CN117267546A - Surveying instrument stabilization support convenient to adjust - Google Patents

Abstract

The invention belongs to the technical field of surveying and mapping, and particularly discloses a surveying instrument stabilizing support convenient to adjust. The invention provides a surveying instrument stabilizing support which can be used for stabilizing and controlling the temperature of an electronic measuring instrument when the electronic measuring instrument is used outdoors, can ensure that a cold source is subjected to efficient cooling operation, and is convenient to adjust and realize the cyclic heat dissipation of the measuring instrument.

Description

Surveying instrument stabilization support convenient to adjust

Technical Field

The invention belongs to the technical field of surveying and mapping, and particularly relates to a surveying and mapping instrument stabilizing support convenient to adjust.

Background

The surveying instrument is one kind of instrument and device for data acquisition, processing, output, etc. and is one for measuring in engineering construction, planning, construction and management.

The current stable support of surveying instrument has the following problems:

when measuring instrument is outdoor to carry out measurement operation, often need to support fixedly to the instrument with the support, traditional measurement support mostly only possesses height, the function of level adjustment, this kind of support is only applicable to measuring tool, and can't satisfy the use to electronic measurement instrument, electronic measurement instrument is long-time operation under outdoor high temperature, on the one hand, measuring instrument itself produces the temperature from inside when the operation, on the other hand, measuring instrument is under outdoor high temperature weather, surrounding environment heats measuring instrument from outside, and then lead to measuring instrument to carry out long-time work under high temperature, the measurement accuracy of measuring instrument of very big influence, shorten the life of instrument, make current measurement support can not satisfy the user demand to measuring instrument in the open air, consequently, a surveying instrument that can stabilize the temperature when the outdoor use to electronic measurement instrument, and can guarantee that the cold source carries out high-efficient cooling operation, realize the surveying instrument steady support to measuring instrument of measuring instrument circulation heat dissipation.

Disclosure of Invention

To above-mentioned condition, for overcoming prior art's defect, this scheme provides one kind and can stabilize the accuse temperature when outdoor use to electronic measuring instrument to can guarantee that the cold source carries out high-efficient cooling operation, realize the surveying instrument steady rest who is convenient for adjust to measuring instrument circulation radiating.

The technical scheme adopted by the scheme is as follows: the utility model provides a stable support of surveying instrument convenient to adjust, including surveying board, centre gripping positioning mechanism, steadiness adjustment mechanism and gravity type circulation mechanism that sinks, centre gripping positioning mechanism locates the surveying board upper wall, steadiness adjustment mechanism locates the surveying board lateral wall, gravity type circulation mechanism that sinks locates the steadiness adjustment mechanism lateral wall, steadiness adjustment mechanism includes one section and bears mechanism and two sections spherical mechanisms, one section bears the mechanism and locates the surveying board lateral wall, one section is born the mechanism and is kept away from the one end of surveying board to one section spherical mechanism, gravity type circulation mechanism that sinks includes operation temperature control mechanism and liquid flow circulation mechanism, operation temperature control mechanism locates the surveying board diapire, liquid flow circulation mechanism locates operation temperature control mechanism diapire.

As the further preference of scheme of this case, clamping positioning mechanism includes grip slipper, guiding hole, grip slipper, fly leaf, grip slipper and clamping spring, multiunit the grip slipper is located the survey and drawing board upper wall, the grip slipper is located the grip slipper upper wall, the grip slipper lateral wall is located to the guiding hole, the guiding hole is located to the grip slipper slip inside, the fly leaf is located grip slipper one side, the fly leaf is located one side that the fly leaf was kept away from to the grip slipper, the fly leaf is located between grip slipper and the fly leaf in the grip slipper outside.

When the electronic measuring instrument is used, the pushing plate is pulled, the pushing plate drives the clamping rod to slide along the guide opening, the clamping rod drives the clamping plate to move back to back through deformation of the clamping spring, the electronic measuring instrument is placed on the upper wall of the mapping plate, the pushing plate is loosened, the clamping spring elastically resets and drives the clamping rod to slide along the guide opening through the pushing plate, and the clamping rod drives the clamping plate to move relatively to clamp and position the electronic measuring instrument.

Preferably, the first section bearing mechanism comprises an adjusting groove, an adjusting screw, a rotating block, a section of support and a locking nut, wherein a plurality of groups of adjusting grooves are formed in the side wall of the mapping plate, the adjusting grooves are communicated, the adjusting screw is arranged on the inner wall of the adjusting groove, the rotating block is rotationally arranged on the outer side of the adjusting screw, the section of support is arranged on the outer side of the rotating block, the locking nuts are symmetrically arranged on the outer sides of the adjusting screw on two sides of the rotating block, and the locking nut is in threaded connection with the adjusting screw; the two-section spherical mechanism comprises a connecting cylinder, two sections of frames, a fixing threaded hole, a fixing bolt, a spherical seat and a conical column, wherein the connecting cylinder is arranged on one side of the section of support, which is far away from the rotating block, the two sections of frames are rotationally arranged at two ends of the connecting cylinder, the fixing threaded hole is formed in the side wall of the two sections of frames, the fixing bolt penetrates through the side wall of the connecting cylinder, one end, which is far away from the connecting cylinder, of the fixing bolt is arranged inside the fixing threaded hole, the fixing bolt is in threaded connection with the fixing threaded hole, the spherical seat is arranged on one side, which is far away from the connecting cylinder, of the two sections of frames, and the conical column is arranged on one side, which is far away from the two sections of frames, of the spherical seat.

When the electronic measuring instrument is used, the locking nut is rotated to be away from the side wall of the rotating block along the adjusting screw, the rotating block rotates around the adjusting screw to drive the first section of support to adjust the supporting position, the fixing bolt is rotated, the fixing bolt is screwed out of the inside of the fixing threaded hole, at the moment, the second section of frame is changed into a movable state from a fixed state, the second section of frame rotates around the connecting cylinder to drive the spherical seat to be placed into a spherical pit dug in advance, the conical column is inserted into the measuring ground, then, the spherical seat is buried into the pit hole by earthing, so that the spherical seat is fixed, the fixing bolt is screwed into the inside of the fixing threaded hole, the second section of frame is changed into a fixed state from the movable state, the locking nut is rotated to the side wall of the rotating block along the adjusting screw, and the locking nut is fixed to the rotating block, and the rotating block is changed into the fixed state from the movable state to the fixed state, so that the fixed placement of the electronic measuring instrument on the upper wall of the measuring board is completed.

The operation temperature control mechanism comprises an annular cylinder, a liquid suction pump, a one-way liquid outlet valve, a liquid outlet spring pipe, a flow distribution spring pipe, a collecting box, a cooling spring pipe, a cooling port, a cooling copper plate, a cooling copper column, thermoelectric cooling fins and a radiator, wherein the annular cylinder is arranged on the bottom wall of the mapping plate, the liquid suction pump is arranged on the inner wall of the annular cylinder, the one-way liquid outlet valve is communicated with the upper wall of the spherical seat, the liquid outlet spring pipe is communicated between the one-way liquid outlet valve and the connecting cylinder, the flow distribution spring pipe is symmetrically arranged on two sides of the connecting cylinder, the flow distribution spring pipe is communicated with the connecting cylinder, the collecting box is communicated between the flow distribution spring pipe, the cooling spring pipe penetrates through the annular cylinder and is communicated between the collecting box and the power input end of the liquid suction pump, a plurality of groups of cooling ports are arranged on the upper wall of the mapping plate, the cooling copper column penetrates through the bottom wall of the cooling port, a plurality of groups of thermoelectric cooling fins penetrate through the inside the annular cylinder, the thermoelectric cooling fins are arranged on the side wall of the spherical seat, the hot end is arranged inside the spherical seat, and the radiator is arranged on the thermoelectric cooling fins; the liquid flow circulation mechanism comprises a one-way liquid return valve, a return spring pipe and a pipeline clamp, wherein a plurality of groups of the one-way liquid return valves are communicated with the bottom wall of the annular cylinder, the return spring pipe is communicated between the one-way liquid return valve and the spherical seat, and the pipeline clamp is arranged between a section of support and the return spring pipe.

During the use, electronic measuring instrument places survey and drawing board upper wall and cooling copper laminating, add clear water to the inside back of annular section of thick bamboo, after the inside clear water that fills of annular section of thick bamboo, manual opening one-way liquid return valve, at this moment, the return spring pipe switches on with the annular section of thick bamboo, the inside clear water of annular section of thick bamboo flows into spherical seat inside through the return spring pipe, thermoelectric refrigeration piece cools off the clear water that enters into spherical seat inside through the refrigeration end, afterwards, one-way drain valve is opened, the suction pump is through the power input end with the inside cold water of spherical seat through the drain spring pipe suction to the connecting cylinder inside, the connecting cylinder shunts cold water, the inside cold water of connecting cylinder enters into the collecting box inside through the shunt spring pipe, the inside cold water of collecting box enters into the annular section of thick bamboo inside through the cooling spring pipe, the inside cold water temperature reduces after the annular section of thick bamboo is through cooling copper post cooling down, the copper temperature reduces the back and dispels the heat to electronic measuring instrument, thereby guarantee electronic measuring instrument's high-efficient operation efficiency.

Wherein, the header lateral wall is equipped with the controller.

Preferably, the controller is electrically connected with the liquid suction pump, the thermoelectric cooling fin and the radiator respectively.

The beneficial effect that this scheme of adoption above-mentioned structure obtained is as follows:

compared with the prior art, this scheme adopts the mode of burying to combine the use of circulating cold water, can dispel the heat operation to the electronic measuring apparatu at outdoor operation, improve electronic measuring apparatu's high-efficient operation, increase its life, guarantee its precision when measuring, can make electronic measuring apparatu adapt to outdoor abominable environment, thereby satisfy current use needs at outdoor measurement to electronic measuring apparatu, avoid electronic measuring apparatu to inhale the connecting cylinder inside through the liquid spring tube at high temperature for a long time, lead to its inside components and parts high temperature that appears, and influence the problem of measuring process, through the sunshade treatment to the cold source, improve the cooling efficiency to cold water, secondly, under the intervention of clear water use, can fill the inside cavity of spherical seat, and then increase its weight, be convenient for better stabilize the surveying board, the second section frame rotates around the connecting cylinder and drives spherical seat and place inside the spherical pit that has dug in advance, the conical column inserts inside the measurement ground, afterwards, the earthing buries spherical seat inside into the hole, the cold water inside the spherical seat is inhaled inside through the liquid spring tube, the connecting cylinder carries out the reposition of redundant personnel cold water, the inside is cooled down through the inside the annular spring tube, the inside the cooling cylinder is cooled down through the inside the annular spring tube entering the inside the cooling cylinder, the inside the cooling cylinder is cooled down through the annular cooling cylinder inside the cooling cylinder, inside the cooling cylinder is cooled down, inside the cooling cylinder is cooled down.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present solution;

FIG. 2 is a perspective view of the present solution;

FIG. 3 is a schematic diagram of an exploded structure of the present solution;

FIG. 4 is a front view of the present solution;

FIG. 5 is a top view of the present solution;

FIG. 6 is a schematic structural view of the stability adjusting mechanism;

FIG. 7 is a partial cross-sectional view of portion A-A of FIG. 5;

FIG. 8 is an enlarged view of the portion I of FIG. 1;

FIG. 9 is an enlarged view of the portion II of FIG. 2;

fig. 10 is an enlarged structural view of a portion III of fig. 6.

Wherein, 1, the surveying and mapping board, 2, clamping and positioning mechanism, 3, the clamping seat, 4, the clamping block, 5, the guiding mouth, 6, the clamping lever, 7, the pushing plate, 8, the clamping plate, 9, the clamping spring, 10, stability adjustment mechanism, 11, one section bearing mechanism, 12, the adjustment tank, 13, the adjusting screw, 14, the rotating block, 15, one section support, 16, locking nut, 17, two-section spherical mechanism, 18, connecting cylinder, 19, two-section support, 20, fixed screw hole, 21, fixing bolt, 22, spherical seat, 23, cone column, 24, gravity sinking circulation mechanism, 25, operation temperature control mechanism, 26, annular cylinder, 27, liquid suction pump, 28, one-way liquid outlet valve, 29, liquid outlet spring pipe, 30, split spring pipe, 31, collecting box, 32, cooling spring pipe, 33, cooling mouth, 34, cooling copper plate, 35, cooling copper column, 36, cooling plate, 37, radiator, 38, liquid circulation mechanism, 39, one-way liquid return valve, 40, return spring pipe, 41, pipeline, 42, controller.

The accompanying drawings are included to provide a further understanding of the present disclosure and are incorporated in and constitute a part of this disclosure, illustrate and do not limit the disclosure.

Detailed Description

The technical solutions in the embodiments of the present solution will be clearly and completely described below with reference to the drawings in the embodiments of the present solution, and it is apparent that the described embodiments are only some embodiments of the present solution, but not all embodiments; all other embodiments, based on the embodiments in this solution, which a person of ordinary skill in the art would obtain without inventive faculty, are within the scope of protection of this solution.

In the description of the present embodiment, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate orientation or positional relationships based on those shown in the drawings, merely to facilitate description of the present embodiment and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and thus should not be construed as limiting the present embodiment.

As shown in fig. 1-10, the stable support of surveying instrument that this scheme provided is convenient for adjust, including surveying board 1, clamping and positioning mechanism 2, steadiness adjustment mechanism 10 and gravity sinking type circulation mechanism 24, clamping and positioning mechanism 2 locates surveying board 1 upper wall, steadiness adjustment mechanism 10 locates surveying board 1 lateral wall, gravity sinking type circulation mechanism 24 locates steadiness adjustment mechanism 10 lateral wall, steadiness adjustment mechanism 10 includes one section and bears mechanism 11 and two-section spherical mechanism 17, one section bears mechanism 11 locates surveying board 1 lateral wall, two-section spherical mechanism 17 locates one section and bears mechanism 11 and keep away from surveying board 1's one end, gravity sinking type circulation mechanism 24 includes operation temperature control mechanism 25 and liquid flow circulation mechanism 38, operation temperature control mechanism 25 locates surveying board 1 diapire, liquid flow circulation mechanism 38 locates operation temperature control mechanism 25 diapire.

The clamping and positioning mechanism 2 comprises clamping seats 3, clamping blocks 4, guide openings 5, clamping rods 6, pushing plates 7, clamping plates 8 and clamping springs 9, wherein multiple groups of clamping seats 3 are arranged on the upper wall of the mapping plate 1, the clamping blocks 4 are arranged on the upper wall of the clamping seats 3, the guide openings 5 are arranged on the side walls of the clamping blocks 4, the clamping rods 6 are slidably arranged inside the guide openings 5, the pushing plates 7 are arranged on one sides of the clamping rods 6, the clamping plates 8 are arranged on one sides, far away from the pushing plates 7, of the clamping rods 6, and the clamping springs 9 are arranged between the clamping blocks 4 and the pushing plates 7 on the outer sides of the clamping rods 6.

The section of bearing mechanism 11 comprises an adjusting groove 12, an adjusting screw rod 13, a rotating block 14, a section of support 15 and a locking nut 16, wherein a plurality of groups of adjusting grooves 12 are formed in the side wall of the surveying and mapping plate 1, the adjusting grooves 12 are arranged in a penetrating mode, the adjusting screw rod 13 is arranged on the inner wall of the adjusting groove 12, the rotating block 14 is rotationally arranged on the outer side of the adjusting screw rod 13, the section of support 15 is arranged on the outer side of the rotating block 14, the locking nuts 16 are symmetrically arranged on the outer sides of the adjusting screw rods 13 on two sides of the rotating block 14, and the locking nuts 16 are in threaded connection with the adjusting screw rods 13; the two-section spherical mechanism 17 comprises a connecting cylinder 18, two-section frames 19, a fixing threaded hole 20, a fixing bolt 21, a spherical seat 22 and a conical column 23, wherein the connecting cylinder 18 is arranged on one side of the one-section frame 15, which is far away from the rotating block 14, the two-section frames 19 are rotationally arranged at two ends of the connecting cylinder 18, the fixing threaded hole 20 is arranged on the side wall of the two-section frames 19, the fixing bolt 21 penetrates through the side wall of the connecting cylinder 18, one end of the fixing bolt 21, which is far away from the connecting cylinder 18, is arranged inside the fixing threaded hole 20, the fixing bolt 21 is in threaded connection with the fixing threaded hole 20, the spherical seat 22 is arranged on one side of the two-section frames 19, which is far away from the connecting cylinder 18, and the conical column 23 is arranged on one side of the spherical seat 22, which is far away from the two-section frames 19.

The operation temperature control mechanism 25 comprises an annular cylinder 26, a liquid absorption pump 27, a one-way liquid outlet valve 28, a liquid outlet spring pipe 29, a split flow spring pipe 30, a collecting box 31, a cooling spring pipe 32, a cooling port 33, a cooling copper plate 34, a cooling copper column 35, thermoelectric cooling fins 36 and a radiator 37, wherein the annular cylinder 26 is arranged on the bottom wall of the mapping plate 1, the liquid absorption pump 27 is arranged on the inner wall of the annular cylinder 26, the one-way liquid outlet valve 28 is communicated and arranged on the upper wall of the spherical seat 22, the liquid outlet spring pipe 29 is communicated and arranged between the one-way liquid outlet valve 28 and the connecting cylinder 18, the split flow spring pipe 30 is symmetrically arranged on two sides of the connecting cylinder 18, the split flow spring pipe 30 is communicated with the connecting cylinder 18, the collecting box 31 is communicated and arranged between the split flow spring pipe 30, the cooling spring pipe 32 penetrates through the annular cylinder 26 and is communicated and arranged between the collecting box 31 and the power input end of the liquid absorption pump 27, a plurality of groups of cooling ports 33 are arranged on the upper wall of the mapping plate 1, the cooling copper plate 34 is arranged on the bottom wall of the cooling port 33, the cooling copper column 35 penetrates through the mapping plate 1 and is arranged in the annular cylinder 26, a plurality of thermoelectric cooling fins 36 are arranged in the thermoelectric cooling fins 36 and penetrate the cooling fins 36 and are arranged in the cooling copper plate 36; the liquid flow circulation mechanism 38 comprises a one-way liquid return valve 39, a return spring pipe 40 and a pipeline clamp 41, a plurality of groups of the one-way liquid return valves 39 are communicated with the bottom wall of the annular cylinder 26, the return spring pipe 40 is communicated between the one-way liquid return valve 39 and the spherical seat 22, and the pipeline clamp 41 is arranged between a section of support 15 and the return spring pipe 40.

The side wall of the collecting box 31 is provided with a controller 42.

The controller 42 is electrically connected to the liquid suction pump 27, the thermoelectric cooling fin 36, and the heat sink 37, respectively.

In specific use, in the first embodiment, four groups of pits are dug in advance at the position where the measuring bracket is placed, the locking nut 16 is manually screwed, the locking nut 16 rotates along the adjusting screw 13 to be far away from the side wall of the rotating block 14, the rotating block 14 rotates around the adjusting screw 13 to drive the first section of bracket 15 to adjust the supporting position, the fixing bolt 21 is manually screwed, the fixing bolt 21 is screwed out of the inside of the fixing threaded hole 20, at this time, the second section of bracket 19 is changed from the fixed state to the movable state, the second section of bracket 19 rotates around the connecting cylinder 18 to drive the spherical seat 22 to be placed in the pre-dug spherical pits, the conical column 23 is inserted into the measuring ground, then the spherical seat 22 is buried in the pits by covering soil, the cooling efficiency of cold source is improved by shading treatment, the fixing bolt 21 is screwed into the inside of the fixing threaded hole 20, the second section of bracket 19 is changed from the movable state to the fixed state by rotating the locking nut 16, the locking nut 16 rotates along the adjusting screw 13 to the side wall of the rotating block 14, the rotating block 14 is fixed by the locking nut 16, and the rotating block 14 is changed from the movable state to the fixed state.

Specifically, the pushing plate 7 is manually pulled, the pushing plate 7 drives the clamping rod 6 to slide along the guide opening 5, the clamping rod 6 drives the clamping plate 8 to move back to back through deformation of the clamping spring 9, an electronic measuring instrument is placed on the upper wall of the surveying and mapping plate 1, the pushing plate 7 is loosened, the clamping spring 9 is elastically reset to drive the clamping rod 6 to slide along the guide opening 5 through the pushing plate 7, and the clamping rod 6 drives the clamping plate 8 to move relatively to clamp and position the electronic measuring instrument, so that the fixed placement of the electronic measuring instrument on the upper wall of the surveying and mapping plate 1 is completed.

In the second embodiment, based on the above embodiment, the electronic measuring instrument is placed on the upper wall of the mapping plate 1 and is attached to the cooling copper plate 34, clean water is added into the annular cylinder 26, after the annular cylinder 26 is filled with clean water, the one-way liquid return valve 39 is manually opened, at this time, the return spring tube 40 is communicated with the annular cylinder 26, the clean water in the annular cylinder 26 flows into the spherical seat 22 through the return spring tube 40, and under the intervention of the clean water, the cavity in the spherical seat 22 can be filled, so that the weight of the cavity is increased, and the mapping plate 1 is convenient to stabilize.

Specifically, the controller 42 controls the thermoelectric cooling fin 36 to start, the thermoelectric cooling fin 36 cools the clean water entering the interior of the spherical seat 22 through the cooling end, the controller 42 controls the radiator 37 to start, the radiator 37 radiates the heat of the thermoelectric cooling fin 36, then, the one-way liquid outlet valve 28 is manually opened, the controller 42 controls the liquid suction pump 27 to start, the liquid suction pump 27 sucks the cold water inside the spherical seat 22 into the connecting cylinder 18 through the liquid outlet spring pipe 29 through the power input end, the connecting cylinder 18 shunts the cold water, the cold water inside the connecting cylinder 18 enters the collecting box 31 through the shunt spring pipe 30, the cold water inside the collecting box 31 enters the annular cylinder 26 through the cooling spring pipe 32, the temperature of the cold water inside the annular cylinder 26 is reduced, the temperature of the cooled copper plate 34 is reduced through the cooling copper column 35, and the electronic measuring instrument is radiated after the temperature of the cooled copper plate 34 is reduced, and therefore the high-efficiency operation of the electronic measuring instrument is guaranteed.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present solution have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations may be made to these embodiments without departing from the principles and spirit of the solution, the scope of which is defined in the appended claims and their equivalents.

The present embodiment and the embodiments thereof have been described above with no limitation, and the embodiment shown in the drawings is merely one of the embodiments of the present embodiment, and the actual structure is not limited thereto. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the technical solution.

Claims (10)

1. Surveying instrument stabilization support convenient to adjust, including survey and drawing board (1), its characterized in that: still include centre gripping positioning mechanism (2), steadiness adjustment mechanism (10) and gravity subsidence circulation mechanism (24), the survey board (1) upper wall is located in centre gripping positioning mechanism (2), survey board (1) lateral wall is located in steadiness adjustment mechanism (10), survey board (1) diapire is located in gravity subsidence circulation mechanism (24), steadiness adjustment mechanism (10) include one section bears mechanism (11) and two sections spherical mechanism (17), one section bears mechanism (11) and locates survey board (1) lateral wall, one section bears mechanism (11) one end of keeping away from survey board (1) is located to two sections spherical mechanism (17), gravity subsidence circulation mechanism (24) are including operation temperature control mechanism (25) and liquid flow circulation mechanism (38), operation temperature control mechanism (25) are located survey board (1) diapire, liquid flow circulation mechanism (38) are located operation temperature control mechanism (25) diapire.

2. The survey meter stabilization support of claim 1 for ease of adjustment, wherein: clamping positioning mechanism (2) are including grip slipper (3), grip block (4), guiding mouth (5), clamping lever (6), push plate (7), grip block (8) and clamping spring (9), multiunit grip slipper (3) are located survey and drawing board (1) upper wall, grip slipper (4) are located grip slipper (3) upper wall, guiding mouth (5) are located grip slipper (4) lateral wall.

3. The survey meter stabilization support of claim 2 for ease of adjustment, wherein: the clamping rod (6) is arranged inside the guide opening (5) in a sliding mode, the pushing plate (7) is arranged on one side of the clamping rod (6), the clamping plate (8) is arranged on one side, far away from the pushing plate (7), of the clamping rod (6), and the clamping spring (9) is arranged between the clamping block (4) and the pushing plate (7) on the outer side of the clamping rod (6).

4. A surveying instrument stabilizing support for easy adjustment according to claim 3, wherein: the utility model discloses a device for measuring and drawing a surveying and mapping plate, including a section mechanism (11), including adjustment tank (12), adjusting screw (13), rotating block (14), a section support (15) and lock nut (16), multiunit adjusting tank (12) are located survey and mapping plate (1) lateral wall, and adjustment tank (12) are link up the setting, adjusting screw (13) are located adjusting tank (12) inner wall, rotating block (14) rotate and are located adjusting screw (13) outside, rotating block (14) outside is located in a section support (15), lock nut (16) symmetry are located adjusting screw (13) outside of rotating block (14) both sides, lock nut (16) and adjusting screw (13) threaded connection.

5. The survey meter stabilization support of claim 4 for ease of adjustment, wherein: the two-section spherical mechanism (17) comprises a connecting cylinder (18), two sections of frames (19), fixing threaded holes (20), fixing bolts (21), spherical seats (22) and conical columns (23), wherein the connecting cylinder (18) is arranged on one side, far away from the rotating block (14), of the one section of support (15), the two sections of frames (19) are rotationally arranged at two ends of the connecting cylinder (18), the fixing threaded holes (20) are formed in the side walls of the two sections of frames (19), and the fixing bolts (21) are arranged on the side walls of the connecting cylinder (18) in a penetrating mode.

6. The survey meter stabilization support of claim 5 for ease of adjustment, wherein: one end of the fixing bolt (21) far away from the connecting cylinder (18) is arranged inside the fixing threaded hole (20), the fixing bolt (21) is in threaded connection with the fixing threaded hole (20), the spherical seat (22) is arranged on one side of the two-section frame (19) far away from the connecting cylinder (18), and the conical column (23) is arranged on one side of the spherical seat (22) far away from the two-section frame (19).

7. The survey meter stabilization mount of claim 6 wherein: the operation temperature control mechanism (25) comprises an annular cylinder (26), a liquid suction pump (27), a one-way liquid outlet valve (28), a liquid outlet spring pipe (29), a flow distribution spring pipe (30), a collecting box (31), a cooling spring pipe (32), a cooling port (33), a cooling copper plate (34), a cooling copper column (35), a thermoelectric cooling plate (36) and a radiator (37), wherein the annular cylinder (26) is arranged on the bottom wall of the mapping plate (1), the liquid suction pump (27) is arranged on the inner wall of the annular cylinder (26), the one-way liquid outlet valve (28) is communicated with the upper wall of the spherical seat (22), and the liquid outlet spring pipe (29) is communicated between the one-way liquid outlet valve (28) and the connecting cylinder (18).

8. The survey meter stabilization mount of claim 7, wherein: the utility model discloses a survey and drawing board, including connecting tube (18), cooling spring pipe (32), connecting tube (18) both sides are located to reposition of redundant personnel spring pipe (30), reposition of redundant personnel spring pipe (30) are linked together with connecting tube (18), between reposition of redundant personnel spring pipe (30) are located in current collector (31) and suction pump (27) power input are located in current collector (26) intercommunication to current collector (31), multiunit cooling mouth (33) are located survey and drawing board (1) upper wall.

9. The survey meter stabilization support of claim 8 for ease of adjustment, wherein: the cooling copper plate (34) is arranged on the bottom wall of the cooling opening (33), the cooling copper columns (35) penetrate through the mapping plate (1) and are arranged inside the annular cylinder (26), a plurality of groups of thermoelectric cooling fins (36) penetrate through the side wall of the spherical seat (22), the cooling ends of the thermoelectric cooling fins (36) are arranged inside the spherical seat (22), and the radiator (37) is arranged on the heating ends of the thermoelectric cooling fins (36).

10. The survey meter stabilization support of claim 9 for ease of adjustment, wherein: the liquid flow circulation mechanism (38) comprises a one-way liquid return valve (39), a return spring pipe (40) and a pipeline clamp (41), wherein a plurality of groups of the one-way liquid return valves (39) are communicated with the bottom wall of the annular cylinder (26), the return spring pipe (40) is communicated between the one-way liquid return valve (39) and the spherical seat (22), and the pipeline clamp (41) is arranged between the one-section support (15) and the return spring pipe (40).