CN208833503U - A kind of lead screw pair transmission efficiency dynamic measurement device - Google Patents

Abstract

The utility model discloses a kind of lead screw pair transmission efficiency dynamic measurement device, which includes fourth gear switching mechanism, lathe bed, workbench, tailstock, motor；Lathe bed includes pedestal and panel, and panel is vertically installed in the upper surface of pedestal；3 groups of closed slides with sliding block vertical with base upper surface are arranged in the side of panel, 3 groups of guide rails are denoted as the first guide rail, the second guide rail, third guide rail respectively from one end, tailstock wherein is set on the sliding block of the second guide rail, and the axis of tailstock is parallel with the second guide rail, and workbench is arranged on the sliding block of the first guide rail and third guide rail；The side of pedestal is arranged one for driving the motor of fourth gear switching mechanism campaign, and motor synchronous pulley is arranged on motor.The utility model, which can measure positive drive, that load, positive drive be non-loaded, inverse transmission has load, inverse is driven non-loaded four kinds of states lower leading screw auxiliary driving efficiency；And vertical structure is used, it can be reduced head, tail frame coaxiality error, reduce lead screw amount of deflection, structure is simple.

Description

A kind of lead screw pair transmission efficiency dynamic measurement device

Technical field

The utility model belongs to lead screw pair dynamic efficiency field, especially a kind of lead screw pair transmission efficiency dynamic measurement dress It sets.

Background technique

In modern manufacturing system, numerically-controlled machine tool plays very important effect to manufacturing industry.In recent years, with domestic number The gradually promotion of machine tool industry technical level is controlled, numerically-controlled machine tool performance has long-range development, and the development of Machine Tool Industry achieves Apparent progress.But from the point of view of machine tool product general technical level, there are also larger gaps for China and international most advanced level, special It is not wanting in some high-performance, high-precision high-end machine tool product away from particularly evident.As numerically-controlled machine tool key feature Transmission agency component, very prominent, urgent need technology the problem of in terms of the measurement of the dynamic of transmission efficiency is with performance characteristics research Tackling key problem is to solve.Therefore, start with from lead screw pair transmission efficiency dynamic measurement with performance study, examine and improve transmission agency component Transmission efficiency have become the task of top priority of domestic transmission agency component manufacturing enterprise, directly influence China's machine industry and dress Standby manufacturing development.

The transmission efficiency of lead screw pair is exactly the ratio of output power and input power, this is the transmission effect theoretically defined Rate, size directly affect the quality of the even entire numerically-controlled machine tool of this lead screw pair.Therefore, lead screw pair transmission efficiency is only carried out Dynamic measurement and comprehensive performance research and analyse the quality that could really improve product, domestic at present to survey in transmission efficiency dynamic The research for measuring aspect is still seldom, improves space with sizable.Experience is generallyd use in lead screw pair efficiency industry Value, specific measuring principle are that the two is divided by as efficiency by measurement output power and input power.Currently, lead screw pair is dynamic State efficiency measurement system is still not perfect, and in topology layout, existing detection device is unable to measure lead screw pair dynamic efficiency；Soft In part processing, there are no special inspection software, need to debug.

Now in order to measure lead screw pair transmission efficiency, common device is then to pass through loading (weight first by lead screw formal dress Code, the modes such as pressurization), lead screw transmission efficiency is measured one by one；Lead screw is dismantled again, anti-to fill, load measures lead screw transmission efficiency. But lead screw transmission efficiency not only inefficiency is measured in this manner, and be not capable of measuring transmission effect when lead screw is inverse to be driven Rate.

Utility model content

The technical issues of the utility model is solved is to provide a kind of lead screw pair transmission efficiency dynamic measurement device.

Realize the technical solution of the utility model aim are as follows: a kind of lead screw pair transmission efficiency dynamic measurement device, packet Include fourth gear switching mechanism, lathe bed, workbench, tailstock, motor；Lathe bed includes pedestal and panel, and panel is vertically installed in pedestal Upper surface；3 groups of closed slides with sliding block vertical with base upper surface are arranged in the side of panel, and 3 groups of guide rails are from one end It is denoted as the first guide rail, the second guide rail, third guide rail respectively, wherein tailstock is arranged on the sliding block of the second guide rail, and the axis of tailstock It is parallel with the second guide rail, workbench is set on the sliding block of the first guide rail and third guide rail；The side of pedestal is arranged one for driving The motor of fourth gear switching mechanism campaign is moved, motor synchronous pulley is set on motor.

Compared with prior art, remarkable advantage: 1) the utility model principle is simple for the utility model, in clamped one time silk After thick stick, can be realized by the conversion of meshing relation between gear measurement positive drive have load, positive drive be non-loaded, inverse transmission have it is negative It carries, the inverse transmission efficiency for being driven non-loaded four kinds of situation lower leading screws；2) the utility model gear shifting action is completed by shifting slide gear, control It makes simple and reliable, substantially increases the practical performance and operating characteristics of device；3) the utility model uses vertical structure, can subtract Small head, tail frame coaxiality error, reduces running-in lead screw amount of deflection, and structure is simple and easy for installation.

The utility model is described in further detail with reference to the accompanying drawing.

Detailed description of the invention

Fig. 1 is the general structure schematic diagram of the utility model lead screw pair transmission efficiency dynamic measurement device.

Fig. 2 is the general structure schematic diagram of the fourth gear switching mechanism of the utility model measuring device.

Fig. 3 is the tested main shaft system schematic diagram of the fourth gear switching mechanism of the utility model measuring device.

Fig. 4 is the spline spindle system schematic diagram of the fourth gear switching mechanism of the utility model measuring device.

Fig. 5 is that accompanying for the fourth gear switching mechanism of the utility model measuring device runs main shaft system schematic diagram.

Fig. 6 is the brake main shaft system schematic diagram of the fourth gear switching mechanism of the utility model measuring device.

Fig. 7 is the tailstock schematic diagram of the utility model measuring device.

Fig. 8 is the workbench schematic diagram of the utility model measuring device.

Fig. 9 is that the positive drive of the utility model measuring device has load gear to be driven flow chart.

Figure 10 is that the non-loaded gear of positive drive of the utility model measuring device is driven flow chart.

Figure 11 is that the inverse transmission of the utility model measuring device has load gear to be driven flow chart.

Figure 12 is that the non-loaded gear of inverse transmission of the utility model measuring device is driven flow chart.

Specific embodiment

In conjunction with Fig. 1, a kind of lead screw pair transmission efficiency dynamic measurement device of the utility model, including fourth gear switching mechanism 1, bed Body 2, workbench 3, tailstock 4, motor 5；Lathe bed 2 includes pedestal 6 and panel 7, and panel 7 is vertically installed in the upper surface of pedestal 6；Face 3 groups of closed slides with sliding block vertical with 6 upper surface of pedestal are arranged in the side of plate 7, and 3 groups of guide rails are remembered respectively from one end For the first guide rail 7-1, the second guide rail 7-2, third guide rail 7-3, wherein tailstock 4 is arranged on the sliding block of the second guide rail 7-2, and tail The axis of frame 4 is parallel with the second guide rail 7-2, and workbench 3 is arranged on the sliding block of the first guide rail 7-1 and third guide rail 7-3；Pedestal 6 Side one motor 5 for driving fourth gear switching mechanism 1 to move is set, motor synchronous pulley 5-1 is set on motor 5.

In conjunction with Fig. 2, the fourth gear switching mechanism 1 includes tested main shaft system 1-1, spline spindle system 1-2, accompanies race main shaft system 1-3, brake main shaft system 1-4, aforementioned four shafting pass through rack and are mounted on pedestal 6, and brake main shaft system 1-4 has one Group gear pair often engages, by the first shifting slide gear 1-2-3 and brake main shaft system 1-4 on mobile spline spindle system 1-2 The second shifting slide gear 1-4-3 position realize fourth gear conversion.

In conjunction with Fig. 3, the tested main shaft system 1-1 includes that expansion set 1-1-1, expansion set seat 1-1-2, expansion set seat drag 1-1-3, first Rack 1-1-4, the first shaft joint 1-1-5, three parameter sensors 1-1-6, second shaft coupling 1-1-7, first gear 1-1-8, One main shaft 1-1-9, the second main shaft 1-1-10；Expansion set seat 1-1-2, the first main shaft 1- is arranged in one end of the first main shaft 1-1-9 One end of the connected first shaft joint 1-1-5 of the other end of 1-9, is arranged between expansion set seat 1-1-2 and the first shaft joint 1-1-5 and is used for First main shaft 1-1-9 is fixed on the first rack 1-1-4 on measurement cabinet, between expansion set seat 1-1-2 and the first rack 1-1-4 Setting expansion set seat drags 1-1-3, and one end on expansion set seat 1-1-2 far from the first rack 1-1-4 is fixed in one end of expansion set 1-1-1, And the other end of expansion set 1-1-1 connects tested lead screw 1-5, the other end and expansion set seat of expansion set seat 1-1-2 drags 1-1-3 to be connected；The One end of the connected three parameter sensors 1-1-6 of the other end of one shaft joint 1-1-5, the other end of three parameter sensors 1-1-6 are solid Even one end of second shaft coupling 1-1-7, one end of the connected second main shaft 1-1-10 of the other end of second shaft coupling 1-1-7, second First gear 1-1-8 is arranged in the other end of main shaft 1-1-10；Tested main shaft system 1-1 and tailstock 4 are coaxially disposed.

In conjunction with Fig. 4, the spline spindle system 1-2 includes splined shaft 1-2-1, the second rack 1-2-2, the first shifting slide gear 1-2-3, the first transmission gear 1-2-4；One end of the splined shaft 1-2-1 is arranged for splined shaft 1-2-1 to be fixed on measurement The first transmission gear 1-2-4, the second rack 1-2-2 is arranged in the other end of the second rack 1-2-2 on cabinet, splined shaft 1-2-1 The first shifting slide gear 1-2-3, the first shifting slide gear 1-2-3 is arranged between the first transmission gear 1-2-4 can be along splined shaft 1-2-1 Axial movement；First shifting slide gear 1-2-3 is meshed with extraneous motor output gear.

In conjunction with Fig. 5, it is described accompany run main shaft system 1-3 include third rack 1-3-2, third shaft coupling 1-3-3, transmission shaft 1-3- 4, the second transmission gear 1-3-5；One end of the connected third shaft coupling 1-3-3 in one end of the transmission shaft 1-3-4, third shaft coupling The second transmission gear 1-3-5, the connected third rack 1-3-2 of the other end of third shaft coupling 1-3-3 is arranged in the other end of 1-3-3 One end, third rack 1-3-2 the other end connection accompanies run lead screw 1-3-1；Third rack 1-3-2 is fixed on measurement cabinet.

In conjunction with Fig. 6, the brake main shaft system 1-4 is slided including the 4th rack 1-4-1, brake connecting shaft 1-4-2, second Move gear 1-4-3, first bevel gear 1-4-4, second bevel gear 1-4-5, transmission main shaft 1-4-6, the 4th shaft coupling 1-4-7, system Dynamic device 1-4-8；The 4th rack 1-4-1 is arranged in one end of the brake connecting shaft 1-4-2, and brake connecting shaft 1-4-2's is another First bevel gear 1-4-4 is arranged in one end, and the second shifting slide gear 1- is arranged between the 4th rack 1-4-1 and first bevel gear 1-4-4 4-3, the second shifting slide gear 1-4-3 can be along the axial movements of brake connecting shaft 1-4-2；One end of the transmission main shaft 1-4-6 Second bevel gear 1-4-5, one end of the connected 4th shaft coupling 1-4-7 of the other end of transmission main shaft 1-4-6, the 4th shaft coupling are set The connected brake 1-4-8 of the other end of 1-4-7；The 4th rack 1-4-1 is fixed on measurement cabinet, first bevel gear 1-4- 4 are meshed with second bevel gear 1-4-5, and brake 1-4-8 is for providing load.

In conjunction with Fig. 7, the tailstock 4 includes tailstock center 4-1, center sleeve 4-2, tailstock 4-3, T-type lead screw 4-4, nut 4-5, handle 4-6 and clamp 4-7；The tailstock 4-3 is hollow body structure, internal that center sleeve 4-2, center sleeve 4- is arranged 2 one end attaching nut 4-5 far from pedestal 6, nut 4-5, T-type lead screw 4-4, handle 4-6 are sequentially connected；The tailstock center 4- 1 is nested in center sleeve 4-2；Handle 4-6 successively drives T-type lead screw 4-4, nut 4-5, center sleeve 4-2, tailstock center 4-1 to exist It is axial to carry out stretching motion；The clamp 4-7 is placed on guide rail, and is connected by connecting plate with tailstock 4-3, for locking Tailstock center 4-1.

In conjunction with Fig. 8, the workbench 3 includes nut fixed station 3-1, attachment base 3-2, attachment base 3-2 and nut fixed station One end of 3-1 is connected；Two are provided on nut fixed station 3-1 between the first guide rail 7-1 and third guide rail 7-3 to lead to Hole, one of through-hole and tested main shaft system 1-1 and tailstock 4 are coaxially disposed, another through-hole and accompany race main shaft system 1-3 coaxial Setting, and the edge of each through-hole is provided with the bolt hole matched with feed screw nut in one week, for fixing the nut of lead screw pair, Nut drives 3 moved in coaxial of workbench.In conjunction with Fig. 1 and Fig. 8, the guide rail institute of the panel 7 on the whole, is provided with parallel with guide rail Several clamp bar slots 8, and several clamp bar slots 8 are ipsilateral relative to nut fixed station 3-1 and attachment base 3-2；It is set in every clamp bar slot M are equipped with the sense base 10 for limiting the movement travel of lead screw pair and the inductive head 9 of limit of sports record position, attachment base 3- The inductive head 9 coaxial with sense base 10 in every clamp bar slot is provided on 2.

Further, m=2.

Further, lathe bed 2 uses metal material.

When fourth gear converted measurement mechanism is in positive drive and has load shelves state, the first sliding tooth on spline spindle system 1-2 Wheel 1-2-3 is meshed with the first gear 1-1-8 on tested main shaft system 1-1, the second sliding tooth on brake main shaft system 1-4 Wheel 1-4-3 is meshed with the second transmission gear 1-3-5 on race main shaft system 1-3 is accompanied.Positive drive has load gear transmission process such as It is specific as follows shown in Fig. 9:

1,5-motor of motor synchronous pulley 5-1-spline spindle transmission gear 1-2-4-shifting slide gear 1-2-3-is tested Mainshaft gear 1-1-8-is tested lead screw 1-5-nut fixed station 3-1-and accompanies race lead screw 1-3-1.

2, brake 1-4-8-second bevel gear 1-4-5-first bevel gear 1-4-4-shifting slide gear 1-4-3-accompanies race Spindle transmission gear 1-3-5-, which is accompanied, runs lead screw 1-3-1.

The first sliding tooth when fourth gear converted measurement mechanism is in positive drive non-loaded shelves state, on spline spindle system 1-2 Wheel 1-2-3 is meshed with the first gear 1-1-8 on tested main shaft system 1-1, the second shifting slide gear on brake main shaft system 1-4 1-4-3 divides equally with the first gear 1-1-8 on the second transmission gear 1-3-5 run on main shaft system 1-3, tested main shaft system 1-1 is accompanied From.Positive drive is non-loaded, and gear transmission process is as shown in Figure 10, specific as follows:

The tested master of 5-motor of motor synchronous pulley 5-1-spline spindle transmission gear 1-2-4-shifting slide gear 1-2-3- Shaft gear 1-1-8-is tested lead screw 1-5-nut fixed station 3-1-and accompanies race lead screw 1-3-1.

When fourth gear converted measurement mechanism is in inverse transmission and has load shelves state, the first sliding tooth on spline spindle system 1-2 Wheel 1-2-3 is meshed with the second transmission gear 1-3-5 on race main shaft system 1-3 is accompanied, and second on brake main shaft system 1-4 is sliding Gear 1-4-3 is moved to be meshed with the first gear 1-1-8 on tested main shaft system 1-1.Inverse transmission has load gear transmission process such as It is specific as follows shown in Figure 11:

1,5-motor of motor synchronous pulley 5-1-spline spindle transmission gear 1-2-4-shifting slide gear 1-2-3-accompanies race Spindle transmission gear 1-3-5-, which is accompanied, runs the tested lead screw 1-5 of lead screw 1-3-1-nut fixed station 3-1-.

2, brake 1-4-8-second bevel gear 1-4-5-first bevel gear 1-4-4-shifting slide gear 1-4-3-is tested Mainshaft gear 1-1-8-is tested lead screw 1-5.

The first sliding tooth when fourth gear converted measurement mechanism is in inverse transmission non-loaded shelves state, on spline spindle system 1-2 Wheel 1-2-3 is meshed with the second transmission gear 1-3-5 on race main shaft system 1-3 is accompanied, and second on brake main shaft system 1-4 is sliding It moves gear 1-4-3 and accompanies the first gear 1- on the second transmission gear 1-3-5 run on main shaft system 1-3, tested main shaft system 1-1 1-8 is separated.The inverse non-loaded gear transmission process of transmission is as shown in figure 12, specific as follows:

5-motor of motor synchronous pulley 5-1-spline spindle transmission gear 1-2-4-shifting slide gear 1-2-3-accompanies race to lead Shaft transmission gear 1-3-5-, which is accompanied, runs the tested lead screw 1-5 of lead screw 1-3-1-nut fixed station 3-1-.

When utility model device works, ball-screw auxiliary driving is carried out using above-mentioned lead screw pair dynamic efficiency measuring device The process of efficiency measurement is that tested main shaft system, tail frame device hold lead screw to be measured, and lead screw is first matched with tested main shaft system expansion set It closes, tailstock is moved on the guide rail being connected on lathe bed by guide rail slide block, and adjustment position is tested main shaft system；Pass through workbench The nut of the fixed lead screw to be measured of nut fixed station, drives guide screw movement to be measured by motor again later to adjust the position of its nut Starting point is measured to lead screw；Then the position for adjusting sense base in card slot, determines movement travel and the limit of sports record of lead screw to be measured Position；Start to measure later:

1, carrying out positive drive has load gear to measure, on the first shifting slide gear and tested main shaft system that spline spindle is fastened First gear be meshed, the second shifting slide gear on brake main shaft system with accompany run main shaft system on the second transmission gear mutually nibble It closes, industrial personal computer issues instruction control motor work, and motor makes expansion set rotation that tested lead screw be driven to revolve by toothed belt transmission Turn；Lead screw rotation drives the nut fixed station on workbench to be axially moved accordingly, so that nut fixed station drives Inductive head on attachment base is coaxially moved；It is collected into lead screw rotation torque, revolving speed, axial force according to computer, determines quilt Survey the transmission efficiency of lead screw.

2, it carries out the non-loaded gear of positive drive to measure, on the first shifting slide gear and tested main shaft system that spline spindle is fastened First gear be meshed, the second shifting slide gear on brake main shaft system with accompany run main shaft system on the second transmission gear and by The first gear surveyed on main shaft system all separates, and industrial personal computer issues instruction control motor work, and motor is made swollen by toothed belt transmission Set rotates and then drives tested lead screw rotation；Lead screw rotation drives the nut fixed station on workbench to carry out corresponding axial fortune It is dynamic, so that nut fixed station drives the inductive head on attachment base coaxially to be moved；Lead screw rotation is collected into according to computer Torque, revolving speed, axial force determine the transmission efficiency of tested lead screw.

3, carrying out inverse transmission has load gear measurement, and the first shifting slide gear that spline spindle is fastened and accompanying is run on main shaft system The second transmission gear be meshed, the second shifting slide gear on brake main shaft system is mutually nibbled with the first gear on tested main shaft system It closes, industrial personal computer issues instruction control motor work, and motor makes expansion set rotation that tested lead screw be driven to revolve by toothed belt transmission Turn；Lead screw rotation drives the nut fixed station on workbench to be axially moved accordingly, so that nut fixed station drives Inductive head on attachment base is coaxially moved；It is collected into lead screw rotation torque, revolving speed, axial force according to computer, determines quilt Survey the transmission efficiency of lead screw.

4, carry out it is inverse be driven non-loaded gear measurement, the first shifting slide gear that spline spindle is fastened and accompanying is run on main shaft system The second transmission gear be meshed, the second shifting slide gear on brake main shaft system with accompany run main shaft system on the second transmission gear It is all separated with the first gear on tested main shaft system, industrial personal computer issues instruction control motor work, and motor passes through toothed belt transmission It rotates expansion set and then drives tested lead screw rotation；It is corresponding axial that lead screw rotation drives the nut fixed station on workbench to carry out Movement, so that nut fixed station drives the inductive head on attachment base coaxially to be moved；Lead screw is collected into according to computer Rotation torque, revolving speed, axial force determine the transmission efficiency of tested lead screw.

Completing above-mentioned positive drive has the measurement of load gear, the measurement of positive drive is non-loaded gear, inverse transmission to have load gear to survey Amount, the inverse non-loaded gear of transmission measure, i.e., completion lead screw pair transmission efficiency dynamic measures.

The utility model is able to satisfy the requirement of ball screw assembly, transmission efficiency measurement, after realizing clamped one time, can measure Positive drive has that load, positive drive be non-loaded, inverse transmission has load, inverse is driven non-loaded four kinds of states lower leading screw auxiliary driving efficiency； And vertical structure is used, it can be reduced head, tail frame coaxiality error, reduce lead screw amount of deflection, structure is simple, easy for installation.

Claims (9)

1. a kind of lead screw pair transmission efficiency dynamic measurement device, which is characterized in that including fourth gear switching mechanism (1), lathe bed (2), Workbench (3), tailstock (4), motor (5)；Lathe bed (2) includes pedestal (6) and panel (7), and panel (7) is vertically installed in pedestal (6) upper surface；3 groups of closed slides with sliding block vertical with pedestal (6) upper surface are arranged in the side of panel (7), and 3 groups are led Rail is denoted as the first guide rail (7-1), the second guide rail (7-2), third guide rail (7-3) respectively from one end, wherein the second guide rail (7-2) Sliding block on tailstock (4) are set, and the axis of tailstock (4) is parallel with the second guide rail (7-2), and the first guide rail (7-1) is led with third Workbench (3) are set on the sliding block of rail (7-3)；The side of pedestal (6) is arranged one for driving fourth gear switching mechanism (1) to move Motor (5), motor synchronous pulley (5-1) is set on motor (5).

2. lead screw pair transmission efficiency dynamic measurement device according to claim 1, which is characterized in that the fourth gear interpreter Structure (1) includes tested main shaft system (1-1), spline spindle system (1-2), accompanies and run main shaft system (1-3), brake main shaft system (1-4), on It states four shaftings and passes through rack and be mounted on pedestal (6), brake main shaft system (1-4) has one group of gear pair often to engage, and passes through The second shifting slide gear on the first shifting slide gear (1-2-3) and brake main shaft system (1-4) on mobile spline spindle system (1-2) Realize fourth gear conversion in the position of (1-4-3).

3. lead screw pair transmission efficiency dynamic measurement device according to claim 2, which is characterized in that the tested main shaft system (1-1) includes that expansion set (1-1-1), expansion set seat (1-1-2), expansion set seat drag (1-1-3), the first rack (1-1-4), the first shaft joint (1-1-5), three parameter sensors (1-1-6), second shaft coupling (1-1-7), first gear (1-1-8), the first main shaft (1-1- 9), the second main shaft (1-1-10)；Expansion set seat (1-1-2) is arranged in one end of first main shaft (1-1-9), the first main shaft (1-1- 9) one end of the other end connected first shaft joint (1-1-5), sets between expansion set seat (1-1-2) and the first shaft joint (1-1-5) Set the first rack (1-1-4) for being fixed on the first main shaft (1-1-9) on measurement cabinet, expansion set seat (1-1-2) and first Expansion set seat is arranged between rack (1-1-4) to drag (1-1-3), one end of expansion set (1-1-1) is fixed on separate on expansion set seat (1-1-2) One end of first rack (1-1-4), and the other end of expansion set (1-1-1) connects tested lead screw (1-5), expansion set seat (1-1-2) The other end and expansion set seat drag (1-1-3) to be connected；The other end of first shaft joint (1-1-5) is connected three parameter sensors (1-1-6) One end, the other ends of three parameter sensors (1-1-6) is connected the one end of second shaft coupling (1-1-7), second shaft coupling (1-1- 7) first gear (1- is arranged in the other end of one end of the other end connected second main shaft (1-1-10), the second main shaft (1-1-10) 1-8)；Tested main shaft system (1-1) and tailstock (4) is coaxially disposed；

The spline spindle system (1-2) include splined shaft (1-2-1), the second rack (1-2-2), the first shifting slide gear (1-2-3), First transmission gear (1-2-4)；One end of the splined shaft (1-2-1) is arranged for splined shaft (1-2-1) to be fixed on measurement The first transmission gear (1-2-4) is arranged in the other end of the second rack (1-2-2) on cabinet, splined shaft (1-2-1), the second rack It is arranged between (1-2-2) and the first transmission gear (1-2-4) the first shifting slide gear (1-2-3), the first shifting slide gear (1-2-3) can Along the axial movement of splined shaft (1-2-1)；First shifting slide gear (1-2-3) is meshed with extraneous motor output gear；

It is described to accompany that run main shaft system (1-3) include third rack (1-3-2), third shaft coupling (1-3-3), transmission shaft (1-3-4), the Two transmission gears (1-3-5)；One end of one end of the transmission shaft (1-3-4) connected third shaft coupling (1-3-3), third shaft coupling The second transmission gear (1-3-5) is arranged in the other end of device (1-3-3), the connected third machine of the other end of third shaft coupling (1-3-3) One end of frame (1-3-2), the other end connection of third rack (1-3-2), which is accompanied, runs lead screw (1-3-1)；Third rack (1-3-2) is solid Due on measurement cabinet；

The brake main shaft system (1-4) includes the 4th rack (1-4-1), brake connecting shaft (1-4-2), the second shifting slide gear (1-4-3), first bevel gear (1-4-4), second bevel gear (1-4-5), transmission main shaft (1-4-6), the 4th shaft coupling (1-4- 7), brake (1-4-8)；The 4th rack (1-4-1), brake connection is arranged in one end of the brake connecting shaft (1-4-2) First bevel gear (1-4-4) is arranged in the other end of axis (1-4-2), between the 4th rack (1-4-1) and first bevel gear (1-4-4) It is arranged the second shifting slide gear (1-4-3), the second shifting slide gear (1-4-3) can be along the axial movement of brake connecting shaft (1-4-2)； Second bevel gear (1-4-5) is arranged in one end of the transmission main shaft (1-4-6), and the other end of transmission main shaft (1-4-6) is connected the The other end of one end of four shaft couplings (1-4-7), the 4th shaft coupling (1-4-7) is connected brake (1-4-8)；4th rack (1-4-1) is fixed on measurement cabinet, and first bevel gear (1-4-4) is meshed with second bevel gear (1-4-5), brake (1- 4-8) for providing load.

4. lead screw pair transmission efficiency dynamic measurement device according to claim 3, which is characterized in that the fourth gear conversion is surveyed When measuring mechanism is in positive drive and has load shelves state, the first shifting slide gear (1-2-3) and tested master in spline spindle system (1-2) First gear (1-1-8) in shafting (1-1) is meshed, the second shifting slide gear (1-4-3) on brake main shaft system (1-4) with The second transmission gear (1-3-5) run on main shaft system (1-3) is accompanied to be meshed；

The first sliding when fourth gear converted measurement mechanism is in positive drive non-loaded shelves state, in spline spindle system (1-2) Gear (1-2-3) is meshed with the first gear (1-1-8) on tested main shaft system (1-1), and on brake main shaft system (1-4) Two shifting slide gears (1-4-3) with accompany the second transmission gear (1-3-5) run on main shaft system (1-3), on tested main shaft system (1-1) First gear (1-1-8) separates；

When fourth gear converted measurement mechanism is in inverse transmission and has load shelves state, the first sliding in spline spindle system (1-2) Gear (1-2-3) is meshed with the second transmission gear (1-3-5) in race main shaft system (1-3) is accompanied, on brake main shaft system (1-4) The second shifting slide gear (1-4-3) be meshed with the first gear (1-1-8) on tested main shaft system (1-1)；

The first sliding when fourth gear converted measurement mechanism is in inverse transmission non-loaded shelves state, in spline spindle system (1-2) Gear (1-2-3) is meshed with the second transmission gear (1-3-5) in race main shaft system (1-3) is accompanied, on brake main shaft system (1-4) The second shifting slide gear (1-4-3) with accompany the second transmission gear (1-3-5) run on main shaft system (1-3), tested main shaft system (1-1) On first gear (1-1-8) separate.

5. lead screw pair transmission efficiency dynamic measurement device according to claim 1, which is characterized in that tailstock (4) packet It includes tailstock center (4-1), center sleeve (4-2), tailstock (4-3), T-type lead screw (4-4), nut (4-5), handle (4-6) and pincers Device (4-7) processed；The tailstock (4-3) is hollow body structure, internal that center sleeve (4-2) is arranged, and center sleeve (4-2) is the bottom of far from One end attaching nut (4-5) of seat (6), nut (4-5), T-type lead screw (4-4), handle (4-6) are sequentially connected；The tailstock top Sharp (4-1) is nested in center sleeve (4-2)；Handle (4-6) successively drives T-type lead screw (4-4), nut (4-5), center sleeve (4- 2), tailstock center (4-1) is axially carrying out stretching motion；The clamp (4-7) is placed on guide rail, and passes through connecting plate and tail Stand (4-3) is connected, for locking tailstock center (4-1).

6. lead screw pair transmission efficiency dynamic measurement device according to claim 1, which is characterized in that the workbench (3) Including nut fixed station (3-1), attachment base (3-2), one end of attachment base (3-2) and nut fixed station (3-1) are connected；Positioned at Two through-holes are provided on nut fixed station (3-1) between one guide rail (7-1) and third guide rail (7-3), one of those is logical Hole is coaxially disposed with tested main shaft system (1-1) and tailstock (4), another through-hole is coaxially disposed with race main shaft system (1-3) is accompanied, and every The edge of a through-hole is provided with the bolt hole matched with feed screw nut in one week, and for fixing the nut of lead screw pair, nut is driven Workbench (3) moved in coaxial.

7. lead screw pair transmission efficiency dynamic measurement device according to claim 1 or 6, which is characterized in that the panel (7) Guide rail institute on the whole, be provided with several clamp bar slots (8) parallel with guide rail, and several clamp bar slots (8) are consolidated relative to nut Determine platform (3-1) and attachment base (3-2) is ipsilateral；Be provided in every clamp bar slot m with for limiting lead screw pair movement travel and The sense base (10) of the inductive head (9) of limit of sports record position is provided with and sense base (10) in every clamp bar slot on attachment base (3-2) Coaxial inductive head (9).

8. lead screw pair transmission efficiency dynamic measurement device according to claim 7, which is characterized in that the m=2.

9. lead screw pair transmission efficiency dynamic measurement device according to claim 1, which is characterized in that the lathe bed (2) is adopted Use metal material.