CN113295319B - Fluid pressure measuring device based on hydrostatic principle - Google Patents

Abstract

The invention discloses a fluid pressure measuring device based on hydrostatic principle, which effectively solves the problem of weak adaptability caused by defects existing in the design of the existing fluid pressure gauge.

Description

Fluid pressure measuring device based on hydrostatic principle

Technical Field

The invention relates to the field of pressure measurement equipment, in particular to a fluid pressure measurement device based on the hydrostatic principle.

Background

The fluid pressure gauge is used for measuring the pressure of fluid, the traditional fluid pressure gauge is divided into a liquid type pressure gauge and a metal pressure gauge, the liquid type pressure gauge is a pressure gauge which is manufactured by utilizing the principle that the pressure generated by the self weight of a liquid column is balanced with the measured pressure based on the hydrostatic principle, and the measuring tube of the liquid type pressure gauge is limited in height and cannot enable the liquid column to rise infinitely, so that the liquid type pressure gauge can only be used for measuring smaller pressure, and when large pressure needs to be measured, the metal pressure gauge in the liquid type pressure gauge needs to be used.

Common metal manometer is the spring manometer, it utilizes the change of spring intraductal pressure to make the pipe free end produce the displacement, its displacement passes through drive mechanism and drives the pointer on the calibrated scale and deflect, with this realization pressure measurement effect, but the spring pipe receives self elasticity limit to influence, elastic deformation is less, it is little to measure fluid pressure value span, based on this, some devices make the improvement to above-mentioned problem, utilize coil spring's elasticity and rack and pinion's transmission, realize the measurement of large-span pressure value, but above-mentioned device still has following drawback:

1. when the elastic coefficient of the coil spring is selected to be relatively small, to realize a large-span pressure measurement, the coil spring needs to be designed to be very long so as to bear the pressure of the measured fluid, and thus, a large design space is occupied.

2. When the elastic coefficient of the coil spring is selected to be relatively large, the length of the coil spring can be greatly shortened, but when the pressure value of the measured fluid is small, the deformation amount of the coil spring is correspondingly small, and when the deformation amount of the coil spring is smaller than the gear side clearance between the gear and the rack, the rack which slightly moves along with the coil spring cannot push the gear to rotate, and at the moment, the device cannot measure the pressure of the measured fluid.

3. Because the transmission of the gear and the rack is adopted, enough space for avoiding the rack is required to be reserved when the device is designed, so that the occupied space of the device is further increased, and the adaptability of the device to various application environments is reduced.

Disclosure of Invention

In view of the above situation, in order to overcome the defects in the prior art, an object of the present invention is to provide a fluid pressure measuring device based on the hydrostatic principle, which can measure a smaller pressure by using the hydrostatic principle and a larger pressure by using the linear spring principle, and has a small overall occupied space and a wide application range.

The technical scheme includes that the fluid pressure measuring device based on the hydrostatic principle comprises a pressure measuring pipe, wherein the pressure measuring pipe comprises a U-shaped pipe and a abdicating pipe, the U-shaped pipe consists of a transition pipe section and two vertical measurement pipe sections, the two measurement pipe sections are communicated through the transition pipe section, the abdicating pipe is coaxial with and communicated with any measurement pipe section, a positioning shaft is arranged on the transition pipe section and is arranged along the radial direction, a partition door matched with the transition pipe section is connected to the positioning shaft in a rotating mode, a gear mechanism is arranged on the transition pipe section, a connecting rod is hinged between the partition door and the gear mechanism, a bearing plate is arranged in any measurement pipe section in a sealing and sliding mode, a plurality of annular teeth are arranged below the bearing plate and are evenly distributed along the vertical direction, the annular teeth are matched with the gear mechanism, an indicating liquid bearing pipe arranged below the bearing plate is arranged in a U, and drives the gear mechanism to operate when the bearing plate moves downwards under the measured fluid pressure, and the gear mechanism drives the partition door to rotate through the connecting rod and enables the partition door to block the transition pipe section;

the sealing sliding fit in the abdicating pipe is provided with a transmission plate, the transmission plate and the abdicating pipe are connected with a transmission spring, when the bearing plate contacts with the transmission plate and pushes the transmission plate to move downwards, the transmission spring gives vertical upward elasticity to the transmission plate, the abdicating pipe is rotatably connected with a belt wheel, a silk ribbon is connected between the belt wheel and the transmission plate, the belt wheel and the abdicating pipe are connected with a torsional spring, the abdicating pipe is fixedly connected with a dial, the dial is rotatably installed with a pointer matched with scales on the dial, and a transmission mechanism is connected between the pointer and the belt wheel.

Preferably, the positioning shaft is arranged along the front-back direction, the gear mechanism comprises an incomplete gear which is arranged in the transition pipe section and is in limit rotary connection with the transition pipe section, the axis of the incomplete gear is arranged along the front-back direction, the free end of the head tooth of the incomplete gear extends into any one measuring pipe section, the head tooth of the incomplete gear is made of an elastomer material, the tail tooth of the incomplete gear is made of an elastomer material, an eccentric shaft is arranged on the incomplete gear, one end of a connecting rod is in rotary connection with the eccentric shaft, and the other end of the connecting rod is hinged with the partition door.

Preferably, the lateral wall of the tube of stepping down on open and be circular-arc and with the coaxial groove of stepping down of tube, the pressure release hole below is arranged in to the groove of stepping down, the tube of stepping down is through groove of stepping down and external intercommunication, it is connected with the moving axis along vertical setting to rotate on the tube of stepping down, fixedly connected with arranges the outside of the tube of stepping down in on the moving axis and with the assorted shutter of groove of stepping down, it has the spout that sets up along the tube axis direction of stepping down to open on the tube of stepping down lateral wall, there is the slider of sliding fit in the spout through spring coupling on the tube of stepping down, both ends stretch into the outer and inner both sides of the tube of stepping down respectively about the slider, the slider is arranged in and is connected with the first helical rack that sets up along the tube axial on the tip of the tube of stepping down outside, the meshing has the second helical rack along horizontal setting on the first helical rack, horizontal sliding connection between second helical rack and the tube of stepping down, be connected with the straight rack that length direction is unanimous on the second helical rack, the meshing has solid cover on the straight rack on the moving axis.

Preferably, the transmission mechanism comprises a main shaft coaxially connected to the belt wheel, a first transmission gear is sleeved on the main shaft, a second transmission gear which is rotatably connected to the abdicating pipe and has a reference circle diameter smaller than that of the first transmission gear is meshed on the first transmission gear, a third transmission gear is coaxially connected to the second transmission gear, a fourth transmission gear which is rotatably sleeved on the main shaft and has a reference circle diameter smaller than that of the third transmission gear is meshed on the third transmission gear, a fifth transmission gear which is sleeved on the main shaft is coaxially connected to the fourth transmission gear, a sixth transmission gear which is rotatably connected to the abdicating pipe and has a reference circle diameter smaller than that of the fifth transmission gear is meshed on the fifth transmission gear, a seventh transmission gear is coaxially connected to the sixth transmission gear, an eighth transmission gear which is rotatably sleeved on the main shaft and has a reference circle diameter smaller than that of the seventh transmission gear is meshed on the seventh transmission gear, the dial is coaxial with the eighth transmission gear, the pointer is composed of a main pointer and an auxiliary pointer, the main pointer is connected with the main shaft, and the auxiliary pointer is connected with the eighth transmission gear.

Preferably, the scale on the dial consists of a main scale and an auxiliary scale, the main scale is matched with the main pointer, the auxiliary scale is matched with the auxiliary pointer, the main scale comprises a plurality of main scale marks which are uniformly distributed along the circumferential direction of the dial, the auxiliary scale comprises a plurality of auxiliary scale marks which are uniformly distributed along the circumferential direction of the dial, and the division value of the main scale is equal to the measuring range of the auxiliary scale.

Due to the adoption of the technical scheme, compared with the prior art, the invention has the following advantages;

1. when the pressure of the measured fluid is small, namely the input pressure enables the deformation of the transmission spring to be smaller than the tooth side clearance between the meshing gears, the pipe can realize the pressure measuring effect by utilizing the hydrostatic principle so as to make up the defect that a linear spring type pressure gauge cannot measure the tiny fluid pressure; when the pressure of the fluid to be measured is large, namely the input pressure exceeds the measuring range of the U-shaped pipe 1, the pressure measuring effect can be achieved through the matching of the transmission spring and the transmission plate, so that the defect that the U-shaped pipe liquid pressure gauge cannot measure large fluid pressure is overcome.

2. The design of the connecting wire belt between the transmission plate and the belt wheel ensures that the device does not need to design a longer abdicating space, thereby reducing the occupied space of the device.

3. When the pressure of the measured fluid far exceeds the range of the dial, the pressure relief function of the pressure relief hole is opened, and the pressure bearing plate still needs to bear the very high impact load of the measured fluid.

4. The main scale and the auxiliary scale are used together, so that the artificial estimation error is avoided, and the accuracy of the device is improved.

Drawings

Fig. 1 is a front view of the present invention.

Fig. 2 is an isometric view of the present invention.

FIG. 3 is an isometric cross-sectional view of the present invention.

Fig. 4 is an enlarged view of a in fig. 3 according to the present invention.

Fig. 5 is an enlarged view of B in fig. 3 according to the present invention.

Fig. 6 is a perspective view of a portion of the transmission mechanism of the present invention.

Fig. 7 is a view showing a connection structure of a slider to a protective door part according to the present invention.

Fig. 8 is a perspective view of the dial portion of the present invention.

FIG. 9 is a front sectional view showing a state where the incomplete gear and the fixed shaft of the present invention are coupled together.

Figure 10 is a perspective view of a pressure bearing column portion of the present invention.

The attached drawings are marked as follows: 1-U-shaped pipe, 2-abdicating pipe, 3-transition pipe, 4-measuring pipe, 5-partition door, 6-positioning shaft, 7-connecting rod, 8-bearing plate, 9-bearing column, 10-annular tooth, 11-transmission plate, 12-annular baffle, 13-transmission spring, 14-support frame, 15-belt wheel, 16-wire belt, 17-circular baffle, 18-torsion spring, 19-dial, 20-incomplete gear, 21-fixed shaft, 22-limit groove, 23-limit block, 24-head tooth, 25-tail tooth, 26-eccentric shaft, 27-pressure relief hole, 28-abdicating groove, 29-moving shaft, 30-protection door, 31-sliding groove, 32-sliding block, 33-first oblique rack, 34-second oblique rack, 35-straight rack, 36-driving gear, 37-first transmission gear, 38-second transmission gear, 39-third transmission gear, 40-fourth transmission gear, 41-fifth transmission gear, 42-sixth transmission gear, 43-seventh transmission gear, 44-eighth transmission gear, 44-scale mark, auxiliary pointer, 50-scale mark, 49-48-pointer, auxiliary scale mark, 50-pointer, and auxiliary scale mark.

Detailed Description

The following description of the present invention will be made in further detail with reference to the accompanying drawings 1 to 10.

Embodiment 1. A fluid pressure measuring device based on the hydrostatic principle, including a pressure measuring tube, the pressure measuring tube includes a U-shaped tube 1 and a abdicating tube 2, the U-shaped tube 1 is composed of a transition tube section 3 and two vertical measuring tube sections 4, the two measuring tube sections 4 are arranged in parallel and respectively arranged at the left and right sides of the transition tube section 3, the left and right ends of the transition tube section 3 correspond to the two measuring tube sections 4 one by one, the end of the transition tube section 3 is communicated with the lower end of the corresponding measuring tube section 4, i.e. the two measuring tube sections 4 are communicated through the transition tube section 3, the abdicating tube 2 is coaxial with the measuring tube section 4 at the right side of the transition tube section 3, the inner diameter of the abdicating tube 2 is equal to the inner diameter of the measuring tube section 4 at the right side of the transition tube section 3, the outer diameter of the abdicating tube 2 is equal to the outer diameter of the measuring tube section 4 at the right side of the transition tube section 3, the abdicating tube 2 is communicated with the measuring tube at the right side of the transition tube section 3, the transition pipe section 3 is provided with a positioning shaft 6 arranged in the transition pipe section 3, the positioning shaft 6 is arranged along the radial direction of the transition pipe section 3, the transition pipe section 3 is internally provided with a horizontal partition door 5, the diameter of the partition door 5 is equal to the inner diameter of the transition pipe section 3, the outer edge surface of the partition door 5 is provided with a through hole along the radial direction of the partition door 5, the through hole is arranged along the front-back direction, the positioning shaft 6 is arranged in the through hole in a penetrating way, the positioning shaft 6 is rotationally connected with the partition door 5 along the axis of the positioning shaft 6, the partition door 5 is matched with the transition pipe section 3, the transition pipe section 3 is provided with a gear mechanism, a connecting rod 7 is hinged between the partition door 5 and the gear mechanism, a circular bearing plate 8 is hermetically and slidably matched in the measurement pipe section 4 on the right side of the transition pipe section 3, the bearing plate 8 is coaxial with the measurement pipe section 4 on the right side of the transition pipe section 3, and a bearing column 9 arranged below the bearing plate 8 is coaxially arranged on the bearing plate 8, the side wall of the pressure bearing column 9 is provided with a plurality of annular teeth 10 which are uniformly distributed along the vertical direction, the annular teeth 10 are coaxial with the pressure bearing column 9, the plurality of annular teeth 10 are matched with the gear mechanism, the indicating liquid arranged below the pressure bearing plate 8 is filled in the U-shaped pipe 1, the liquid level of the indicating liquid is flush with the lower end face of the pressure bearing plate 8, when the pressure bearing plate 8 is subjected to the pressure of the fluid to be measured and moves downwards in the measuring pipe section 4 on the right side of the transition pipe section 3, the indicating liquid in the measuring pipe section 4 on the right side of the transition pipe section 3 is pressed downwards by the pressure bearing plate 8, so that the liquid level of the indicating liquid in the measuring pipe section 4 on the right side of the transition pipe section 3 moves downwards, the indicating liquid in the other measuring pipe section 4 moves upwards under the action of the pressure, the liquid levels of the indicating liquid in the two measuring pipe sections 4 generate a height difference, meanwhile, the pressure bearing plate 8 drives the pressure bearing column 9 to move downwards, the pressure bearing column 9 drives the annular teeth 10 to move downwards, when the annular teeth 10 are contacted with the gear mechanism, the annular teeth 10 drive the gear mechanism to rotate, the gear mechanism through the connecting rod 7 to drive the partition door 5 to rotate, so that the partition door 5 blocks the transition pipe section 3;

a circular transmission plate 11 is hermetically and slidably matched in the abdicating pipe 2, the transmission plate 11 is coaxial with the abdicating pipe 2 and is arranged at the upper end of the abdicating pipe 2, an annular baffle plate 12 is coaxially arranged at the bottom end of the abdicating pipe 2, a vertical transmission spring 13 is connected between the transmission plate 11 and the annular baffle plate 12, when the measured fluid pressure is large, so that the pressure bearing column 9 moves to be contacted with the transmission plate 11, the pressure bearing plate 8, the pressure bearing column 9 and the annular teeth 10 just plug the communication part between the measurement pipe section 4 at the right side of the transition pipe section 3 and the transition pipe section 3, at the moment, the partition door 5 plugs the transition pipe section 3, most of the indicating liquid enters the measurement pipe section 4 at the left side of the transition pipe section 3 and is plugged in the measurement pipe section 4 at the left side of the transition pipe section 3 by the partition door 5, when the pressure bearing plate 8 continues to push the transmission plate 11 to move downwards under the pressure of the measured fluid, the transmission spring 13 gives the transmission plate 11 a vertical upward elastic force, the bearing plate 8, the bearing column 9 and the annular teeth 10 gradually open the communication position between the measurement pipe section 4 and the transition pipe section 3 on the right side of the transition pipe section 3, the measured fluid enters the communication section between the measurement pipe section 4 and the transition pipe section 3 on the right side of the transition pipe, and the measured fluid extrudes a small part of the indicating liquid on the right side of the partition door 5, but because the partition door 5 seals the transition pipe section 3, the pressure transmitted to the indicating liquid by the measured fluid can only act on the partition door 5 and is counteracted by the supporting force provided by the partition door 5, therefore, the pressure of the measured fluid can not act on the indicating liquid on the left side of the partition door 5 (namely, the indicating liquid in the measurement pipe section 4 on the left side of the transition pipe section 3), and the problem that the indicating liquid in the measurement pipe section 4 on the left side of the transition pipe section 3 continuously rises when the transmission plate 11 is subjected to pressure downward movement is avoided, the indicating liquid is prevented from overflowing from the measuring pipe section 4 during measurement, the support frame 14 arranged below the annular baffle 12 is connected to the abdicating pipe 2, the support frame 14 is rotatably connected with belt wheels 15 with axes arranged along the front and back directions, a vertical silk ribbon 16 is connected between the belt wheels 15 and the transmission plate 11, coaxial circular baffles 17 are respectively arranged at the front end and the back end of each belt wheel 15, the distance between the two circular baffles 17 is equal to the width of the silk ribbon 16, the silk ribbon 16 penetrates through a center hole of the annular baffle 12, a torsion spring 18 arranged along the front and back directions is connected between each belt wheel 15 and the support frame 14, the elastic force of the torsion spring 18 and the elastic force of the transmission spring 13 are balanced, the stiffness coefficient of the transmission spring 13 is far larger than the stiffness coefficient of the torsion spring 18, the abdicating pipe 2 is fixedly connected with a dial 19, the dial 19 is coaxial with the belt wheels 15, a pointer matched with the scale on the dial 19 is rotatably installed on the dial 19, a transmission mechanism is connected between the pointer and the transmission mechanism 15, when the transmission plate 11 is pressed and moved downwards, the silk ribbon 16 is rotated under the action of the torsion spring 18, and the pointer is displayed by the pressure of the pointer.

Embodiment 2, on the basis of embodiment 1, the positioning shaft 6 is arranged along the front-back direction, the gear mechanism includes an incomplete gear 20 arranged in the transition pipe section 3, the axis of the incomplete gear 20 is arranged along the front-back direction, the incomplete gear 20 is arranged on the upper right side of the transition pipe section 3, a fixed shaft 21 penetrating through an inner hole of the incomplete gear 20 is arranged on the transition pipe section 3, a limit groove 22 with an arc-shaped path is formed on the side wall of the fixed shaft 21, the arc-shaped path of the limit groove 22 is coaxial with the fixed shaft 21, a limit block 23 arranged in the limit groove 22 and in sliding fit with the limit groove 22 is arranged on the incomplete gear 20, so as to form a limit rotary connection between the incomplete gear 20 and the transition pipe section 3, at this time, the limit block 23 is positioned at the initial end position of the limit groove 22, the toothed part of the incomplete gear 20 is arranged above the incomplete gear 20, the right end of the head tooth 24 of the incomplete gear 20 extends into the measuring pipe section 4 on the right side of the transition pipe section 3, the head tooth 24 of the incomplete gear 20 is made of an elastomer material, the tail tooth 25 of the incomplete gear 20 is made of an elastomer material, an eccentric shaft 26 is arranged on the front end face of the incomplete gear 20, the axis of the eccentric shaft 26 is parallel to the axis of the incomplete gear 20, one end of the connecting rod 7 is rotatably connected with the eccentric shaft 26 (namely, one end of the connecting rod 7 is hinged with the incomplete gear 20), the other end of the connecting rod 7 is hinged with the partition door 5 through a shaft arranged along the front-back direction, the connecting rod 7 faces to the radial direction of the incomplete gear 20 at the moment, when the annular tooth 10 is contacted with the gear mechanism (namely, the annular tooth 10 is contacted with the head tooth 24 of the incomplete gear 20), the annular tooth 10 starts to be meshed with the incomplete gear 20, the downward movement of the annular tooth 10 drives the incomplete gear 20 to rotate, the connecting rod 7 to do plane movement by the incomplete gear 20, the connecting rod 7 drives the partition door 5 to rotate, when the pressure bearing column 9 is in contact with the transmission plate 11, the connecting rod 7 faces the radial direction of the incomplete gear 20 again, at the moment, the partition door 5 is changed into a vertical state and seals the transition pipe section 3, at the moment, the free end of the tail tooth 25 extends into the measuring pipe section 4 on the right side of the transition pipe section 3, at the moment, the limiting block 23 slides to the tail end of the stroke, at the moment, the plurality of annular teeth 10 all move to the lower side of the tail tooth 25, and the pressure bearing plate 8 is located above the tail tooth 25; when the bearing plate 8 continues to push the transmission plate 11 downwards through the bearing columns 9, the limit block 23 slides to the stroke end, namely the incomplete gear 20 rotates to the limit position, so the bearing plate 8 cannot push the end teeth 25 to rotate, only the end teeth 25 can be pressed and the end teeth 25 can be contracted, after the bearing plate 8 passes over the end teeth 25, the end teeth 25 are reset under the action of self elastic force, when the bearing plate 8 moves upwards and resets, the bearing plate 8 firstly contacts with the end teeth 25 and pushes the end teeth 25 to rotate, the end teeth 25 push the incomplete gear 20 to rotate reversely, meanwhile, the plurality of annular teeth 10 are meshed with the teeth on the incomplete gear 20 for transmission, when the incomplete gear 20 resets, namely the incomplete gear 20 reversely rotates to the limit position, the free end (namely the right end) of the head tooth 24 of the incomplete gear 20 reenters into the measurement pipe section 4 on the right side of the transition pipe section 3, at the moment, the annular tooth 10 below the head tooth 24 presses the head tooth 24 and forces the head tooth 24 to contract, and after the annular tooth 10 completely passes over the head tooth 24, the head tooth 24 is reset under the action of self elastic force.

Embodiment 3, on the basis of embodiment 1, the sidewall of the abdicating tube 2 is provided with a pressure relief hole 27 near the bottom end of the abdicating tube 2, when the measured fluid pressure exceeds the measuring range of the dial 19, the pressure-bearing plate 8 will cross the pressure relief hole 27 under the action of the measured fluid pressure, so that the measured fluid pressure is released from the pressure relief hole 27 to prevent the device from being damaged by high pressure.

Embodiment 4, on the basis of embodiment 3, the side wall of the abdicating tube 2 is provided with an abdicating groove 28 which is arc-shaped and coaxial with the abdicating tube 2, the abdicating groove 28 is arranged below the pressure relief hole 27, the abdicating tube 2 is communicated with the outside through the abdicating groove 28, the abdicating tube 2 is rotatably connected with a moving shaft 29 which is vertically arranged, the moving shaft 29 is arranged in the abdicating groove 28, the moving shaft 29 is fixedly connected with a protective door 30 which is arranged at the outer side of the abdicating tube 2 and matched with the abdicating groove 28, the protective door 30 is horizontally arranged, the side wall of the abdicating tube 2 is provided with a sliding groove 31 which is arranged along the axial direction of the abdicating tube 2, the sliding groove 31 is arranged at the left side of the abdicating tube 2, the sliding groove 31 is slidably matched with a sliding block 32, the sliding block 32 is connected with the abdicating tube 2 through a vertical spring, the spring between the sliding block 32 and the abdicating tube 2 gives upward force to the sliding block 32, the sliding block 32 extends into the outer side of the abdicating tube 2, the left end of the sliding block 32 extends into the inner side of the abdicating tube 2, a first helical rack 33 arranged along the axial direction of the abdicating pipe 2 is arranged on the outer side of the abdicating pipe 2, the first helical rack 33 is arranged on the left side of the abdicating pipe 2, the end part of the slide block 32 arranged on the outer side of the abdicating pipe 2 is connected with the first helical rack 33 through a rod, the included angle between the tooth line on the first helical rack 33 and the length direction of the first helical rack 33 is 45 degrees, a second helical rack 34 arranged along the transverse direction is meshed on the first helical rack 33, the second helical rack 34 is connected with the abdicating pipe 2 in a transverse sliding way, the second helical rack 34 is arranged below the protective door 30, the included angle between the tooth line on the second helical rack 34 and the length direction of the second helical rack 34 is 45 degrees, a straight rack 35 is connected on the second helical rack 34, the straight rack 35 is arranged on the right side of the second helical rack 34, the length directions of the straight rack 35 and the second helical rack 34 are consistent, the lower end of the moving shaft 29 is penetrated through the side wall of the abdicating pipe 2 and is flush with the lower end surface of the straight rack 35, the spur rack 35 is engaged with a driving gear 36 fixedly sleeved on the moving shaft 29, when the pressure of the fluid to be measured far exceeds the range of the dial 19, the pressure-bearing plate 8 still needs to bear the very high impact load of the fluid to be measured after crossing the pressure relief hole 27, the transmission plate 11 will contact with the right end of the slide block 32 and push the slide block 32 to move downwards, the slide block 32 drives the first helical rack 33 to move downwards, the first helical rack 33 drives the second helical rack 34 to move leftwards, the second helical rack 34 drives the spur rack 35 to move leftwards, the spur rack 35 drives the driving gear 36 to rotate, the driving gear 36 drives the moving shaft 29 to rotate, the moving shaft 29 drives the protective door 30 to rotate, the protective door 30 enters the abdication pipe 2 through the abdication groove 28 and enables a part of the impact load of the fluid to be acted on the protective door 30, and further the impact load borne by the pressure-bearing plate 8 is lightened, so that the transmission spring 13 does not need to be compressed all the time to overcome the impact load, the overload fracture of the transmission spring 13 is avoided, and the device is protected.

Embodiment 5, on the basis of embodiment 1, the transmission mechanism includes a main shaft 47 coaxially connected to the belt pulley 15, a first transmission gear 37 is fixedly sleeved on the main shaft 47, a second transmission gear 38 rotatably connected to the abdicating pipe 2 and having a reference circle diameter smaller than that of the first transmission gear 37 is meshed on the first transmission gear 37, a third transmission gear 39 is coaxially connected to the second transmission gear 38, a sixth transmission gear 42 rotatably connected to the abdicating pipe 2 and having a reference circle diameter smaller than that of the fifth transmission gear 41 is meshed on the third transmission gear 39, a seventh transmission gear 43 is coaxially connected to the sixth transmission gear 42, an eighth transmission gear 44, having a reference circle diameter smaller than that of the seventh transmission gear 43, is meshed on the seventh transmission gear 43 and rotatably sleeved on the main shaft 47, an eighth transmission gear 44, a dial 19, and an eighth transmission gear 44, are rotatably connected to the abdicating pipe 2 and having a reference circle diameter smaller than that of the fifth transmission gear 41, a seventh transmission gear 43 is coaxially connected to the sixth transmission gear 42, an eighth transmission gear 44, and an indicator 48, which are coaxially connected to the main shaft 47, and an indicator sleeve 48, and a sleeve 48, is slidably connected to the main shaft 47.

Embodiment 6, on the basis of embodiment 5, the scale on the dial 19 is composed of a main scale and an auxiliary scale, the main scale is matched with the main pointer 45, the auxiliary scale is matched with the auxiliary pointer 46, the main scale comprises a plurality of main scale marks 49 uniformly distributed along the circumferential direction of the dial 19, the auxiliary scale comprises a plurality of auxiliary scale marks 50 uniformly distributed along the circumferential direction of the dial 19, the main scale is close to the axis of the dial 19 relative to the auxiliary scale, the division value of the main scale is equal to the range of the auxiliary scale, the main pointer 45 points to the 0 scale mark of the main scale in the initial state, and the auxiliary pointer 46 points to the 0 scale mark of the auxiliary scale in the initial state.

When the belt wheel 15 rotates, the main shaft 47 is driven to rotate, the main shaft 47 drives the main pointer 45 to rotate, meanwhile, the main shaft 47 drives the first transmission gear 37 to rotate, the first transmission gear 37 drives the second transmission gear 38 to rotate, the second transmission gear 38 drives the third transmission gear 39 to rotate, the third transmission gear 39 drives the fourth transmission gear 40 to rotate, the fourth transmission gear 40 drives the fifth transmission gear 41 to rotate, the fifth transmission gear 41 drives the sixth transmission gear 42 to rotate, the sixth transmission gear 42 drives the seventh gear 43 to rotate, the seventh gear 43 drives the eighth transmission gear 44 to rotate, the eighth transmission gear 44 drives the sleeve 48 to rotate, the sleeve 48 drives the auxiliary pointer 46 to rotate, when the rotation angle of the main pointer 45 is equal to the included angle between two adjacent main scale lines 49, the rotation angle of the auxiliary pointer 46 is equal to 360 degrees, that is, when reading is performed, when the main pointer 45 is located between two adjacent main scale lines 49, the value of the main scale line 49 with the smaller number in the two main scale lines 49 is read first, then the value of the auxiliary pointer 46 is read, and the flow rate of the measurement error of the two measurement is obtained, and the measurement error is measured.

Embodiment 7 is based on embodiment 1, the measuring pipe section 4 is provided with a graduated scale 51 arranged along the axial direction of the measuring pipe section 4, when the measured fluid pressure is small and the pointer on the dial 19 is not enough to rotate, the scale 51 can directly read the indication corresponding to the liquid level of the indicating liquid in the measuring pipe section 4, and the difference between the two indications is the measured value of the measured fluid pressure.

In embodiment 8, on the basis of embodiment 1, a sealing gasket 52 is coaxially arranged on the outer edge of the partition door 5.

Embodiment 9, on the basis of embodiment 1, the ribbon 16 is a thin ribbon, and the material of the ribbon 16 may be polypropylene material, nylon yarn, etc., which is designed to reduce the system error in the device to the maximum extent.

In embodiment 10, in addition to embodiment 2, the material of the first tooth 24 of the incomplete gear 20 may be specifically butadiene rubber, isoprene rubber, etc., and the material of the last tooth 25 of the incomplete gear 20 may be specifically butadiene rubber, isoprene rubber, etc.

When the device is used, the measuring pipe section 4 on the right side of the transition pipe section 3 is vertically placed and connected to a measured part, a measured fluid flows into the measuring pipe section 4 on the right side of the transition pipe section 3 from the measured part, when the pressure of the measured fluid is lower, the transmission spring 13 slightly deforms, and because a tooth side gap exists between meshed gears, when the slight deformation of the transmission spring 13 is smaller than the tooth side gap, the pointer cannot rotate, the dial 19 cannot test the fluid pressure, and at the moment, the measured fluid pushes the pressure bearing plate 8 to move downwards, so that the liquid levels of indicating liquid in the two measuring pipe sections 4 have a height difference, and the minute pressure of the measured fluid can be measured by using the height difference; when the pressure of the measured fluid exceeds the range of the U-shaped pipe 1, the pressure bearing plate 8 pushes the transmission plate 11 to move downwards under the action of higher pressure, at the moment, the partition door 5 seals the transition pipe section 3, so that mutual interference between two measurement modes (namely the measurement of the U-shaped pipe 1 and the measurement of the transmission spring 13) is avoided, the pointer rotates due to the downward movement of the transmission plate 11, and when the transmission plate 11 stops moving downwards, the indication number on the dial 19 is read, so that the measured value of the pressure of the measured fluid can be obtained.

In the invention, when the U-shaped pipe 1 is used for measuring input pressure, friction force exists between the pressure bearing plate 8 and the corresponding measuring pipe section, so that the friction force between the pressure bearing plate 8 and the measuring pipe section 4 on the right side of the transition pipe section 3 can be reduced to the minimum by reducing the thickness of the pressure bearing plate 8, the roughness of the contact surface and other technological measures, and further the system error of the device is reduced; correction values may also be introduced to eliminate systematic errors introduced by the device itself.

When the transmission spring 13 is used for measurement, friction force exists between the pressure bearing plate 8 and the abdicating pipe 2, between the transmission plate 11 and the abdicating pipe 2, between the meshing gears, between the gears and the main shaft, and between the belt pulley 15 and the support frame 14, and some ways can be adopted to reduce friction force, such as reducing the area of the contact surface, reducing the roughness of the contact surface, and adding lubricating oil to lubricate the contact position (under the condition that the condition allows), so as to reduce the system error of the device; correction values may also be introduced to eliminate systematic errors introduced by the device itself.

When the fluid pressure measurement is performed by the transmission spring 13 after the system error caused by the device itself is reduced or eliminated, the elastic force of the transmission spring 13 is equal to the sum of the pressure of the measured fluid and the torsion force of the torsion spring 18.

Because the radius of the pulley 15 is constant, there is a linear relationship between the length of the silk ribbon wound on the pulley 15 and the torsion angle of the torsion spring 18, the length of the silk ribbon wound on the pulley 15 is the downward moving amount of the transmission plate 11, the downward moving amount of the transmission plate 11 is the variation amount of the transmission spring 13, the elastic force of the transmission spring 13 and the variation amount of the transmission spring 13 have a linear relationship, so the elastic force of the transmission spring 13 and the torsion angle have a linear relationship, and the torsion force of the torsion spring 18 and the torsion angle have a linear relationship, so the difference between the elastic force of the transmission spring 13 and the torsion force of the torsion spring 18 and the torsion angle also have a linear relationship, so the pressure of the measured fluid and the torsion angle of the torsion spring 18 have a linear relationship, and the rotation angle of the pointer has a linear relationship, based on this, the device of the invention can measure the magnitude of the fluid pressure.

While the invention has been described in further detail with reference to specific embodiments thereof, it is not intended that the invention be limited to the specific embodiments thereof; for those skilled in the art to which the present invention pertains and related technologies, the extension, operation method and data replacement should fall within the protection scope of the present invention based on the technical solution of the present invention.

Claims (8)

1. A fluid pressure measuring device based on the hydrostatic principle comprises a pressure measuring pipe and is characterized in that the pressure measuring pipe comprises a U-shaped pipe (1) and a yielding pipe (2), the U-shaped pipe (1) consists of a transition pipe section (3) and two vertical measuring pipe sections (4) which are transversely arranged, the two measuring pipe sections (4) are communicated through the transition pipe section (3), the abdicating pipe (2) is coaxial with any measuring pipe section (4) and communicated with the same diameter, the transition pipe section (3) is provided with a positioning shaft (6) which is arranged in the transition pipe section (3) along the radial direction, the positioning shaft (6) is connected with a partition door (5) matched with the transition pipe section (3) in a rotating way, the transition pipe section (3) is provided with a gear mechanism, a connecting rod (7) is hinged between the partition door (5) and the gear mechanism, a bearing plate (8) is arranged in any measurement pipe section (4) in a sealing and sliding fit manner, a plurality of annular teeth (10) which are arranged below the bearing plate (8) and are uniformly distributed along the vertical direction are arranged on the bearing plate (8), the plurality of annular teeth (10) are matched with the gear mechanism, and indication liquid arranged below the bearing plate (8) is arranged in the U-shaped pipe (1), when the pressure bearing plate (8) moves downwards under the pressure of the measured fluid, the annular tooth (10) drives the gear mechanism to operate, the gear mechanism drives the partition door (5) to rotate through the connecting rod (7) and enables the partition door (5) to plug the transition pipe section (3);

the inside of the abdicating pipe (2) is hermetically matched with a transmission plate (11) in a sliding mode, a transmission spring (13) is connected between the transmission plate (11) and the abdicating pipe (2), when the bearing plate (8) contacts with the transmission plate (11) and pushes the transmission plate (11) to move downwards, the transmission spring (13) gives vertical upward elastic force to the transmission plate (11), the abdicating pipe (2) is rotatably connected with a belt wheel (15), a silk ribbon (16) is connected between the belt wheel (15) and the transmission plate (11), a torsion spring (18) is connected between the belt wheel (15) and the abdicating pipe (2), the abdicating pipe (2) is fixedly connected with a dial (19), a pointer matched with scales on the dial (19) is rotatably installed on the dial (19), and a transmission mechanism is connected between the pointer and the belt wheel (15).

2. The hydrostatic principle-based fluid pressure measuring device of claim 1, wherein the positioning shaft (6) is arranged in a front-rear direction, the gear mechanism comprises an incomplete gear (20) which is arranged in the transition pipe section (3) and is in limited rotational connection with the transition pipe section (3), an axis of the incomplete gear (20) is arranged in the front-rear direction, a free end of a head tooth (24) of the incomplete gear (20) extends into any one of the measuring pipe sections (4), the head tooth (24) of the incomplete gear (20) is made of an elastomer material, a tail tooth (25) of the incomplete gear (20) is made of an elastomer material, an eccentric shaft (26) is arranged on the incomplete gear (20), one end of the connecting rod (7) is rotationally connected with the eccentric shaft (26), and the other end of the connecting rod (7) is hinged with the partition door (5).

3. The hydrostatic-principle-based fluid pressure measuring device of claim 1, wherein the side wall of the abdicating tube (2) is provided with a pressure relief hole (27).

4. The fluid pressure measuring device based on the hydrostatic principle according to claim 3, wherein the side wall of the abdicating tube (2) is provided with an abdicating groove (28) which is arc-shaped and coaxial with the abdicating tube (2), the abdicating groove (28) is arranged below the pressure relief hole (27), the abdicating tube (2) is communicated with the outside through the abdicating groove (28), the abdicating tube (2) is rotatably connected with a moving shaft (29) which is vertically arranged, the moving shaft (29) is fixedly connected with a protective door (30) which is arranged at the outer side of the abdicating tube (2) and is matched with the abdicating groove (28), the side wall of the abdicating tube (2) is provided with a sliding groove (31) which is arranged along the axial direction of the abdicating tube (2), the abdicating pipe (2) is connected with a sliding block (32) which is in sliding fit in the sliding groove (31) through a spring, the left end and the right end of the sliding block (32) respectively extend into the outer side and the inner side of the abdicating pipe (2), the sliding block (32) is arranged on the end part of the outer side of the abdicating pipe (2) and is connected with a first helical rack (33) which is axially arranged along the abdicating pipe (2), a second helical rack (34) which is transversely arranged is meshed on the first helical rack (33), the second helical rack (34) is connected with the abdicating pipe (2) in a transverse sliding way, a straight rack (35) with the same length direction is connected on the second helical rack (34), a driving gear (36) which is fixedly sleeved on the moving shaft (29) is meshed on the straight rack (35) ).

5. The fluid pressure measuring device based on the hydrostatic principle as claimed in claim 1, wherein the transmission mechanism includes a main shaft (47) coaxially connected to the pulley (15), a first transmission gear (37) is fixedly sleeved on the main shaft (47), a second transmission gear (38) rotatably connected to the offset pipe (2) and having a pitch circle diameter smaller than that of the first transmission gear (37) is meshed with the first transmission gear (37), a third transmission gear (39) is coaxially connected to the second transmission gear (38), a fourth transmission gear (40) rotatably sleeved on the main shaft (47) and having a pitch circle diameter smaller than that of the third transmission gear (39) is meshed with the third transmission gear (39), a fifth transmission gear (41) coaxially connected to the main shaft (47) and sleeved on the fourth transmission gear (40), a sixth transmission gear (42) rotatably connected to the offset pipe (2) and having a pitch circle diameter smaller than that of the fifth transmission gear (41) is meshed on the fifth transmission gear (41), a seventh transmission gear (43) is coaxially connected to the sixth transmission gear (42), a seventh transmission gear (43) is coaxially meshed with the seventh transmission gear (43) and a seventh transmission gear (43) and having a pitch circle diameter smaller than that of the eighth transmission gear (44) and that of the eighth transmission gear (19), the pointer consists of a main pointer (45) and an auxiliary pointer (46), the main pointer (45) is connected with a main shaft (47), and the auxiliary pointer (46) is connected with an eighth transmission gear (44).

6. A hydrostatic-principle-based fluid pressure measuring device according to claim 5, wherein the scale on the scale disk (19) is composed of a main scale, which is associated with the main pointer (45), and an auxiliary scale, which is associated with the auxiliary pointer (46), the main scale including a plurality of main scale marks (49) uniformly distributed in the circumferential direction of the scale disk (19), the auxiliary scale including a plurality of auxiliary scale marks (50) uniformly distributed in the circumferential direction of the scale disk (19), the division value of the main scale being equal to the range of the auxiliary scale marks.

7. The hydrostatic-principle-based fluid pressure measuring device according to claim 1, wherein the measuring pipe section (4) of the U-shaped pipe (1) is provided with a scale (51) arranged along the axial direction of the measuring pipe section (4).

8. Hydrostatic-principle-based fluid pressure measuring device according to claim 1, characterized in that the partition door (5) has a sealing gasket (52) coaxially provided on its outer edge.

Images