CN211061520U - Thermodynamic system water quality testing device - Google Patents

Abstract

The utility model provides a thermodynamic system water quality testing device. Thermodynamic system water quality testing device, including the box, the first casing of one side fixedly connected with at box inner wall top, the inside fixedly connected with battery of first casing, the first backup pad of fixedly connected with between the both sides of box inner wall, the top fixedly connected with signal transmitter of first backup pad, the outside that the box just extended to the box is run through on signal transmitter's top, fixedly connected with second backup pad between the both sides of box inner wall. The utility model provides a pair of thermodynamic system water quality testing device has scalable heat-resisting test probe, and electrode detection and battery, heat-resisting flexible probe can protect the integrality of probe not fragile can also work under high temperature quality of water, and electrode detection can be more accurate the impurity content of detection quality of water, and the battery has guaranteed to continue to use under the outdoor no electric condition.

Description

Thermodynamic system water quality testing device

Technical Field

The utility model relates to a water quality testing field especially relates to a thermodynamic system water quality testing device.

Background

Water is a source of life, people can not leave water in life and production activities, and the quality of drinking water is closely related to the health of people. With the development of social economy, scientific progress and improvement of the living standard of people, the requirements of people on the water quality of drinking water are continuously improved, and the water quality standard of the drinking water is correspondingly continuously developed and improved. The water quality standard of the drinking water is established according to various factors such as living habits, cultures, economic conditions, scientific and technical development levels, water resources and water quality situations of people, and the requirements on the quality of the drinking water are different among countries and different regions of the same country, so that the water quality detection is one of important means for ensuring healthy drinking water of people.

Because the existing detection method is based on the reflection degree of impurities in water, if the existing detection method meets high temperature or works outdoors, the existing water quality monitor is difficult to play a role under special conditions, which can cause inaccurate measurement and incapability of working.

Therefore, it is necessary to provide a thermodynamic system water quality detection device to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a, solved the inaccurate of current water quality monitoring device high temperature operation, the difficult problem of outdoor operations.

In order to solve the technical problem, the utility model provides a thermodynamic system water quality detection device, which comprises a box body, wherein one side of the top of the inner wall of the box body is fixedly connected with a first shell, the inside of the first shell is fixedly connected with a storage battery, a first supporting plate is fixedly connected between two sides of the inner wall of the box body, the top of the first supporting plate is fixedly connected with a signal transmitter, the top end of the signal transmitter penetrates through the box body and extends to the outside of the box body, a second supporting plate is fixedly connected between two sides of the inner wall of the box body, the top of the second supporting plate is fixedly connected with a data analyzer, the top of the data analyzer is electrically connected with a first electric wire, one end of the first electric wire penetrates through the first supporting plate and extends to the top of the first supporting plate, one end of the first electric wire, which is, the bottom fixedly connected with electrode box of second backup pad, electrode box's top electric connection has the second electric wire, the one end of second electric wire runs through the second backup pad and extends the top of second backup pad, the one end that the second electric wire is located second backup pad top is connected with data analysis electromechanics electric connection, the both sides of second backup pad bottom are from the right side to left side respectively first slide rail of fixedly connected with and second slide rail, the inside difference sliding connection of first slide rail and second slide rail has first tooth frame and second tooth frame.

Preferably, the bottom of the first tooth frame is fixedly connected with a first high-temperature probe, and the bottom of the second tooth frame is fixedly connected with a second high-temperature probe.

Preferably, the back fixedly connected with second casing of box inner wall, the first motor of inside fixedly connected with of second casing, the first transmission shaft of output shaft fixedly connected with of first motor, the inside that second casing and first tooth frame just extended to first tooth frame is run through in proper order to the one end of first transmission shaft, first transmission shaft is located the first gear of the inside one end fixedly connected with of first tooth frame, the both sides and the meshing of first tooth frame of first gear, the fixed surface of first transmission shaft is connected with first belt pulley.

Preferably, the back of box inner wall rotates and is connected with the second transfer line, the one end of second transfer line runs through first tooth frame and extends to the inside of first tooth frame, the second transfer line is located the inside one end fixedly connected with second gear of first tooth frame, the both sides and the meshing of first tooth frame of second gear, the fixed surface of second transfer line is connected with the second belt pulley, the surface of first belt pulley is passed through the belt and is connected with the surface transmission of second belt pulley.

Preferably, the back fixedly connected with third casing of box inner wall, the inside fixedly connected with second motor of third casing, the output shaft fixedly connected with third transmission shaft of second motor, the one end of third transmission shaft runs through third casing and second tooth frame in proper order and extends to the inside of second tooth frame, the one end fixedly connected with third gear that the third transmission shaft is located the inside of second tooth frame, the both sides and the meshing of second tooth frame of third gear, the fixed surface of third transmission shaft is connected with the third belt pulley.

Preferably, one side of the inner wall of the box body is rotatably connected with a fourth transmission rod, one end of the fourth transmission rod penetrates through the second gear frame and extends into the second gear frame, one end of the fourth transmission rod, which is located inside the second gear frame, is fixedly connected with a fourth gear, two sides of the fourth gear are meshed with the second gear frame, a fourth belt pulley is fixedly connected to the surface of the fourth transmission rod, and the surface of the third belt pulley is in transmission connection with the surface of the fourth belt pulley through a belt.

Compared with the prior art, the utility model provides a pair of thermodynamic system water quality testing device has following beneficial effect:

the utility model provides a thermodynamic system water quality detection device, which is characterized in that a first motor is firstly turned on, a first transmission shaft starts to rotate, the second transmission shaft is driven to rotate by the first belt, the first rotating shaft and the second rotating shaft drive the first gear and the second gear to rotate, the first high-temperature probe is moved downwards to the limit position, the second motor is turned on, the third transmission shaft starts to rotate, the fourth transmission shaft is driven to rotate by the second belt, the third rotating shaft and the fourth rotating shaft drive the third gear and the fourth gear to rotate, the second high-temperature probe moves to the limit position, the electrode box is electrified to transmit the detected water quality to the data analyzer, the data analyzer transmits the information to the signal transmitter, and a remote receiver can receive the water quality detection information, if no electricity exists outdoors, the storage battery can be opened to ensure the normal operation of the box body.

Drawings

Fig. 1 is a schematic structural diagram of a preferred embodiment of a thermodynamic system water quality detection device provided by the present invention;

FIG. 2 is a right side view of the interior of the enclosure shown in FIG. 1;

FIG. 3 is a schematic left side view of the interior of the case shown in FIG. 1;

FIG. 4 is a schematic structural view of the tooth frame shown in FIG. 1;

FIG. 5 is a schematic view of the first pulley shown in FIG. 1;

fig. 6 is a schematic structural view of the second pulley shown in fig. 1.

Reference numbers in the figures: 1. the device comprises a box body, 2, a first shell, 3, a storage battery, 4, a first electric wire, 5, a first supporting plate, 6, a data analyzer, 7, a second supporting plate, 8, a first gear, 9, a second gear, 10, a first slide rail set, 11, a signal transmitter, 12, a second electric wire, 13, an electrode box, 14, a second slide rail set, 15, a second shell, 16, a first belt pulley, 17, a first motor, 18, a first transmission shaft, 19, a second transmission shaft, 20, a first high-temperature probe, 21, a third gear, 22, a fourth gear, 23, a second high-temperature probe, 24, a second belt pulley, 25, a third belt pulley, 26, a fourth belt pulley, 27, a third transmission shaft, 28, a fourth transmission shaft, 29, a second motor, 30, a first gear frame, 31, a second gear frame, 32, a third shell, 33, a first belt, 34 and a second belt.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and embodiments.

Please refer to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5 and fig. 6, in which fig. 1 is a schematic structural diagram of a preferred embodiment of a water quality detecting device for a thermodynamic system according to the present invention; FIG. 2 is a right side view of the interior of the enclosure shown in FIG. 1; FIG. 3 is a schematic left side view of the interior of the case shown in FIG. 1; FIG. 4 is a schematic structural view of the tooth frame shown in FIG. 1; FIG. 5 is a schematic view of the pulley of FIG. 1; fig. 6 is a schematic structural view of the second pulley shown in fig. 1. A thermodynamic system water quality detection device comprises a box body 1, wherein one side of the top of the inner wall of the box body 1 is fixedly connected with a first shell body 2, the inside of the first shell body 2 is fixedly connected with a storage battery 3, a first supporting plate 5 is fixedly connected between two sides of the inner wall of the box body 1, the top of the first supporting plate 5 is fixedly connected with a signal emitter 11, the top end of the signal emitter 11 penetrates through the box body 1 and extends to the outside of the box body 1, a second supporting plate 7 is fixedly connected between two sides of the inner wall of the box body 1, the top of the second supporting plate 7 is fixedly connected with a data analyzer 6, the top of the data analyzer 6 is electrically connected with a first electric wire 4, one end of the first electric wire 4 penetrates through the first supporting plate 5 and extends to the top of the first supporting plate 5, and one end, positioned at the top of the first supporting plate 5, of the, the bottom fixedly connected with electrode box 13 of second backup pad 7, the top electric connection of electrode box 13 has second electric wire 12, the one end of second electric wire 12 runs through second backup pad 7 and extends the top of second backup pad 7, the one end and the data analysis machine 6 electric connection that second electric wire 12 is located the second backup pad 7 top, the both sides of second backup pad 7 bottom are from the right side to left fixedly connected with first slide rail 10 and second slide rail 14 respectively, the inside of first slide rail 10 and second slide rail 14 sliding connection respectively has first rack 30 and second rack 31.

The bottom of the first gear frame 30 is fixedly connected with a first high-temperature probe 20, and the bottom of the second gear frame 31 is fixedly connected with a second high-temperature probe 23.

The back fixedly connected with second casing 15 of the inner wall of box 1, the inside fixedly connected with first motor 17 of second casing 15, the output shaft fixedly connected with first transmission shaft 18 of first motor 17, the one end of first transmission shaft 18 runs through second casing 15 and first tooth frame 30 in proper order and extends to the inside of first tooth frame 30, first transmission shaft 18 is located the inside one end fixedly connected with first gear 8 of first tooth frame 30, the both sides of first gear 8 and the meshing of first tooth frame 30, the fixed surface of first transmission shaft 18 is connected with first belt pulley 16.

The back of box 1 inner wall rotates and is connected with second transfer line 19, the one end of second transfer line 19 runs through first tooth frame 30 and extends to the inside of first tooth frame 30, second transfer line 19 is located the inside one end fixedly connected with second gear 9 of first tooth frame 30, the both sides and the meshing of first tooth frame 30 of second gear 9, the fixed surface of second transfer line 19 is connected with second belt pulley 24, the surface of first belt pulley 16 is connected through belt 34 and the surface transmission of second belt pulley 24 and can makes two first gears 8 and second gear 9 rotate simultaneously, stretches out first high temperature probe 20 box 1.

The back fixedly connected with third casing 32 of box 1 inner wall, the inside fixedly connected with second motor 29 of third casing 32, the output shaft fixedly connected with third transmission shaft (27) of second motor 29, the inside that third casing 32 and second rack 31 just extended to second rack 31 is run through in proper order to the one end of third transmission shaft 27, third transmission shaft 27 is located the inside one end fixedly connected with third gear 21 of second rack 31, the both sides and the meshing of second rack 31 of third gear 21, the fixed surface of third transmission shaft 27 is connected with third belt pulley 25.

One side of box 1 inner wall is rotated and is connected with fourth transfer line 28, the one end of fourth transfer line 28 runs through second rack 31 and extends to the inside of second rack 31, the one end fixedly connected with fourth gear 22 that fourth transfer line 28 is located the inside of second rack 31, the both sides and the meshing of second rack 31 of fourth gear 22, the fixed surface of fourth transfer line 28 is connected with fourth belt pulley 26, the surface transmission of third belt pulley 25 through belt 35 and fourth belt pulley 26 is connected and can is made two third gear 21 and fourth gear 22 rotate simultaneously, can stretch out box 1 simultaneously with first high temperature probe 20 with second high temperature probe 23.

The utility model provides a pair of thermodynamic system water quality testing device's theory of operation as follows:

firstly, a first motor 17 is started, the motor 17 drives a first transmission shaft 18 to rotate, the first transmission shaft 18 drives a second transmission shaft 19 to rotate through a first belt 33, the first transmission shaft 18 and the second transmission shaft 19 drive a first gear 8 and a second gear 9 to rotate, a first gear frame 30 meshed with the first gear 8 and the second gear 9 moves downwards to extend a first high-temperature probe 20 out of a box body 1, then a second motor 29 is started, the motor 29 drives a third transmission shaft 27 to rotate, the third transmission shaft 27 drives a fourth transmission shaft 28 to rotate through a second belt 34, the third transmission shaft 27 and the fourth transmission shaft 28 drive a third gear 21 and a fourth gear 22 to rotate, a second gear frame 31 meshed with the third gear 21 and the fourth gear 22 moves downwards to extend a second high-temperature probe 23 out of the box body 1, an electrode box 13 is electrified, and a numerical value is transmitted to a data analyzer 6 through a second electric wire 12, the data analysis machine 6 communicates data to the signal transmitter 11 via the first electrical line 4, for example, to open the battery 3 for outdoor work.

Compared with the prior art, the utility model provides a pair of thermodynamic system water quality testing device has following beneficial effect:

firstly, the first motor 17 is turned on, the first transmission shaft 18 starts to rotate, the second transmission shaft 19 is driven to rotate through the first belt 33, the first rotation shaft 18 and the second rotation shaft 19 drive the first gear 8 and the second gear 9 to rotate, the first high-temperature probe 20 is moved downwards to the limit position, then the second motor 29 is turned on, the third transmission shaft 27 starts to rotate, the fourth transmission shaft 28 is driven to rotate by the second belt 34, the third rotation shaft 27 and the fourth rotation shaft 28 drive the third gear 21 and the fourth gear 22 to rotate, the second high-temperature probe 23 moves downwards to the limit position, the electrode box 13 is electrified to transmit the detected water quality to the data analyzer 6, the data analyzer 6 transmits the information to the signal transmitter 11, and a remote receiver can receive the water quality detection information, if there is no electricity outdoors, the battery 3 may be turned on to ensure the normal operation of the case 1.

The above only is the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes of the present invention are used in the specification and the attached drawings, or directly or indirectly applied to other related technical fields, and the same principle is included in the protection scope of the present invention.

Claims (6)

1. The utility model provides a thermodynamic system water quality testing device, includes box (1), its characterized in that: the portable power box is characterized in that a first shell (2) is fixedly connected to one side of the top of the inner wall of the box body (1), a storage battery (3) is fixedly connected to the inside of the first shell (2), a first supporting plate (5) is fixedly connected between the two sides of the inner wall of the box body (1), a signal transmitter (11) is fixedly connected to the top of the first supporting plate (5), the top end of the signal transmitter (11) penetrates through the box body (1) and extends to the outside of the box body (1), a second supporting plate (7) is fixedly connected between the two sides of the inner wall of the box body (1), a data analyzer (6) is fixedly connected to the top of the second supporting plate (7), a first wire (4) is electrically connected to the top of the data analyzer (6), one end of the first wire (4) penetrates through the first supporting plate (5) and extends to the top of the first supporting plate, one end that first electric wire (4) are located first backup pad (5) top and signal transmitter (11) electric connection, the bottom fixedly connected with electrode box (13) of second backup pad (7), the top electric connection of electrode box (13) has second electric wire (12), the one end of second electric wire (12) runs through second backup pad (7) and extends the top of second backup pad (7), one end and data analysis machine (6) electric connection that second electric wire (12) are located second backup pad (7) top, the both sides of second backup pad (7) bottom are from the right side to the left side respectively first slide rail (10) and second slide rail (14) of fixedly connected with, the inside difference sliding connection of first slide rail (10) and second slide rail (14) has first tooth frame (30) and second tooth frame (31).

2. The thermodynamic system water quality detection device as claimed in claim 1, wherein a first high temperature probe (20) is fixedly connected to the bottom of the first gear frame (30), and a second high temperature probe (23) is fixedly connected to the bottom of the second gear frame (31).

3. The thermodynamic system water quality detection device as in claim 1, the back of the inner wall of the box body (1) is fixedly connected with a second shell (15), the interior of the second shell (15) is fixedly connected with a first motor (17), the output shaft of the first motor (17) is fixedly connected with a first transmission shaft (18), a first belt pulley (16) is arranged on the first transmission shaft (18), one end of the first transmission shaft (18) penetrates through the second shell (15) and the first gear frame (30) in sequence and extends to the interior of the first gear frame (30), one end of the first transmission shaft (18) positioned in the first gear frame (30) is fixedly connected with a first gear (8), two sides of the first gear (8) are meshed with the first gear frame (30), and a first belt pulley (16) is fixedly connected to the surface of the first transmission shaft (18).

4. A water quality detecting device for a thermodynamic system as claimed in claim 3, wherein the back of the inner wall of the box body (1) is rotatably connected with a second transmission rod (19), one end of the second transmission rod (19) penetrates through the first gear frame (30) and extends to the inside of the first gear frame (30), one end of the second transmission rod (19) located inside the first gear frame (30) is fixedly connected with a second gear (9), two sides of the second gear (9) are engaged with the first gear frame (30), the surface of the second transmission rod (19) is fixedly connected with a second belt pulley (24), and the surface of the first belt pulley (16) is in transmission connection with the surface of the second belt pulley (24) through a first belt (33).

5. The water quality detection device of the thermodynamic system according to claim 1, wherein a third casing (32) is fixedly connected to the back surface of the inner wall of the box body (1), a second motor (29) is fixedly connected to the inside of the third casing (32), a third transmission shaft (27) is fixedly connected to an output shaft of the second motor (29), one end of the third transmission shaft (27) sequentially penetrates through the third casing (32) and the second rack (31) and extends to the inside of the second rack (31), a third gear (21) is fixedly connected to one end of the third transmission shaft (27) located inside the second rack (31), two sides of the third gear (21) are engaged with the second rack (31), and a third belt pulley (25) is fixedly connected to the surface of the third transmission shaft (27).

6. A water quality detection device of a thermodynamic system as claimed in claim 5, wherein one side of the inner wall of the box body (1) is rotatably connected with a fourth transmission rod (28), one end of the fourth transmission rod (28) penetrates through the second gear frame (31) and extends to the inside of the second gear frame (31), one end of the fourth transmission rod (28) located inside the second gear frame (31) is fixedly connected with a fourth gear (22), two sides of the fourth gear (22) are meshed with the second gear frame (31), the surface of the fourth transmission rod (28) is fixedly connected with a fourth belt pulley (26), and the surface of the third belt pulley (25) is in transmission connection with the surface of the fourth belt pulley (26) through a second belt (34).

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