CN220438214U - Oblique temperature layer testing device of energy storage equipment - Google Patents

Abstract

The utility model discloses an energy storage equipment inclined temperature layer testing device which comprises a shell, wherein the middle part of the shell is fixedly connected with a baffle plate, a first chamber and a second chamber are formed in two sides of the interior of the shell, four sliding grooves are formed in two sides of the first chamber and the second chamber, four sliding blocks are connected in the four sliding grooves in a sliding manner, one side of each of the four sliding blocks is fixedly connected with two detection plates, one side of each of the two detection plates is mutually close to one side of each of the two detection plates and is fixedly connected with a plurality of detection heads, the top surface of the baffle plate is provided with a slot, an inclined temperature layer body is inserted in the slot, the top of the first chamber and the top of the second chamber are fixedly communicated with two water inlet pipes, one side of each of the two water inlet pipes is rotatably connected with two sealing covers, one side of the first chamber is fixedly connected with a refrigerating plate, and one side of the second chamber is fixedly connected with a heating plate. According to the utility model, through the cooperation of all the components, the inclined temperature layer body is placed in the slot, the servo motor is turned on, the slide block drives the detection plate to reciprocate, the detection head can accurately test the inclined temperature layer body for a plurality of times, the test accuracy is good, and the test accuracy is ensured.

Description

Oblique temperature layer testing device of energy storage equipment

Technical Field

The utility model relates to the technical field of inclined temperature layers, in particular to an inclined temperature layer testing device of energy storage equipment.

Background

The energy storage device is an energy storage device: a device for receiving energy, storing energy and releasing energy as needed. Some batteries receive energy at a low rate (low power) for longer time intervals and deliver energy at a high rate (high power) for shorter time intervals. Some batteries accept energy at a high rate for a short period of time and deliver energy at a low rate for a longer period of time. In the natural layered water energy storage device, a gradient region with larger temperature change is generated between low-temperature water and high-temperature water, and the region is commonly called an inclined temperature layer, and functions as a boundary line to isolate the low-temperature water from the high-temperature water and prevent the low-temperature water from being mixed with the high-temperature water in the vertical direction, so that the thickness of the inclined temperature layer is an important index for evaluating the performance of the energy storage device. When the oblique temperature layer is used, the oblique temperature layer needs to be tested so as to be used better.

In this regard, the chinese utility model with the authority of CN105203231B discloses a method and a system for dynamically monitoring a water energy storage inclined temperature layer, which comprises: s1, collecting a temperature value Ti sensed by a temperature sensor in an energy storage device; s2, determining a temperature interval of the thickness of the inclined temperature layer according to the following formula; wherein θ is a dimensionless temperature; tc is the cold water temperature preset by the energy storage device, and Th is the warm water temperature preset by the energy storage device; when theta is 0.125-0.875, determining the temperature range of Ti, in which the temperature of which the theta is changed from 0.125-0.875, is the thickness of the oblique temperature layer; s3, acquiring a flow value Q1 of an upper water pipe or a lower water pipe of the energy storage device when the theta is 0.125 through Ti, and acquiring a flow value Q2 of the upper water pipe or the lower water pipe of the energy storage device when the theta is 0.875 through Ti; s4, calculating the thickness Hi of the inclined temperature layer at the position of the temperature sensor according to the following formula: hi=IQ1-Q2I/A; a is the cross-sectional area of the energy storage device.

According to the method and the system for dynamically monitoring the water energy storage inclined temperature layer, the measurement accuracy of the thickness of the inclined temperature layer is improved; the method and the system for dynamically monitoring the water energy storage inclined temperature layer have the advantages that the requirements on the arrangement and the number of temperature sensors are reduced, but when the water energy storage inclined temperature layer is tested, only a single test is performed, the test accuracy is poor, the test accuracy cannot be ensured, and therefore the inclined temperature layer testing device of the energy storage equipment is provided for solving the problems.

Disclosure of Invention

The utility model aims to provide an oblique temperature layer testing device of energy storage equipment, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an energy storage equipment inclined temperature layer testing arrangement, includes the casing, casing middle part fixed connection baffle, cavity one and cavity two are seted up to the inside both sides of casing, four spouts are seted up to cavity one and cavity two both sides, four the inside sliding connection of spout four two pick-up plates of slider one side fixed connection, two a plurality of detection heads of side fixed connection are close to each other to the pick-up plate, the fluting is seted up to the baffle top surface, the inside grafting inclined temperature layer body of fluting.

Preferably, the first chamber and the second chamber are fixed at the top and are communicated with two water inlet pipes, and one side of each water inlet pipe is rotatably connected with two sealing covers.

Preferably, one side of the first chamber is fixedly connected with a refrigerating plate, and one side of the second chamber is fixedly connected with a heating plate.

Preferably, a square cavity I is formed in the center of the bottom of the shell, a servo motor is fixedly connected in the square cavity I, a bevel gear I is fixedly connected to a rotating shaft of the servo motor, two bevel gears II are connected in a meshed mode, two bevel gears II are fixedly connected with one ends of two rotating rods I, and two bevel gears III are fixedly connected with the other ends of the rotating rods I.

Preferably, the three meshing connection of two bevel gears is four bevel gears, four bevel gears four fixed connection four dwang two's one end, four two other end fixed connection four bevel gears five of dwang, four bevel gears five meshing connection four bevel gears six, four six fixed connection four reciprocating screw rods of bevel gears, four reciprocating screw rods rotate and connect four spouts, four reciprocating screw rod threaded structure cover establishes four sliders.

Preferably, two square cavities II and four square cavities III are formed in two sides of the bottom of the shell, the bevel gear V and the bevel gear V are located in the square cavities III, the bevel gear V and the bevel gear V are located in the square cavities II, and the bevel gear I and the bevel gear V are located in the square cavities I.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, through the cooperation of all the components, the inclined temperature layer body is placed in the slot, the servo motor is turned on, the slide block drives the detection plate to reciprocate, the detection head can accurately test the inclined temperature layer body for a plurality of times, the test accuracy is good, and the test accuracy is ensured.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic cross-sectional view of the present utility model;

FIG. 3 is a schematic cross-sectional view of the present utility model;

FIG. 4 is an enlarged schematic view of the utility model at A in FIG. 2;

fig. 5 is an enlarged schematic view of fig. 2B in accordance with the present utility model.

In the figure: 1. a housing; 2. a partition plate; 3. a first chamber; 4. a second chamber; 5. a chute; 6. a slide block; 7. a detection plate; 8. a detection head; 9. slotting; 10. an oblique temperature layer body; 11. a water inlet pipe; 12. sealing cover; 13. a heating plate; 14. a refrigeration plate; 15. square cavity I; 16. a servo motor; 17. bevel gears I; 18. bevel gears II; 19. rotating the first rod; 20. bevel gears III; 21. bevel gears IV; 22. square cavity II; 23. a second rotating rod; 24. a bevel gear V; 25. a square cavity III; 26. a bevel gear six; 27. and (5) a reciprocating screw rod.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

Referring to fig. 1-3, in a first embodiment of the present utility model, a device for testing an inclined temperature layer of an energy storage device is provided, including a housing 1, a partition board 2 is fixedly connected in the middle of the housing 1, a first chamber 3 and a second chamber 4 are provided at two sides of the interior of the housing 1, four sliding grooves 5 are provided at two sides of the first chamber 3 and the second chamber 4, four sliding grooves 5 are slidably connected with four sliding blocks 6, two detection plates 7 are fixedly connected at one side of the four sliding blocks 6, two detection plates 7 are mutually close to one another and fixedly connected with a plurality of detection heads 8, a slot 9 is provided at the top surface of the partition board 2, an inclined temperature layer body 10 is inserted into the slot 9, the thickness of the partition board 2 is thinner, the inclined temperature layer body 10 is not affected, when in use, cold water is added into the first chamber 3, hot water is added into the second chamber 4, then the inclined temperature layer body 10 is inserted into the slot 9, the sliding blocks 6 move in the sliding grooves 5, the sliding blocks 6 move the detection plates 7, the movement of the detection heads 8 move, and the detection heads 8 move.

Example 2

Referring to fig. 1 and 3, the top parts of the first chamber 3 and the second chamber 4 are fixed and communicated with two water inlet pipes 11, one side of each water inlet pipe 11 is rotatably connected with two sealing covers 12, the water inlet pipe 11 is used for adding hot water and cold water, and the sealing covers 12 are used for sealing the water inlet pipe 11.

Referring to fig. 3, one side of the first chamber 3 is fixedly connected with a refrigerating plate 14, the refrigerating plate 14 helps to refrigerate cold water in the first chamber 3, one side of the second chamber 4 is fixedly connected with a heating plate 13, and the heating plate 13 helps to heat hot water in the second chamber 4.

Referring to fig. 2 and fig. 4-5, a square cavity one 15 is formed in the center of the bottom of the shell 1, a servo motor 16 is fixedly connected inside the square cavity one 15, a bevel gear one 17 is fixedly connected to a rotating shaft of the servo motor 16, the bevel gear one 17 is connected with two bevel gears two 18 in a meshed mode, the two bevel gears two 18 are fixedly connected with one ends of two rotating rods one 19, the other ends of the two rotating rods one 19 are fixedly connected with two bevel gears three 20, the servo motor 16 is turned on, the servo motor 16 rotates to drive the bevel gears one 17 to rotate, the bevel gears one 17 rotates to drive the bevel gears two 18 to rotate, the bevel gears two 18 rotate to drive the rotating rods one 19 to rotate, and the rotating rods one 19 rotate to drive the bevel gears three 20 to rotate.

Referring to fig. 2 and 4-5, the two bevel gears three 20 are in meshed connection with four bevel gears four 21, the four bevel gears four 21 are fixedly connected with one end of a four rotating rod two 23, the other end of the four rotating rod two 23 is fixedly connected with four bevel gears five 24, the four bevel gears five 24 are in meshed connection with four bevel gears six 26, the four bevel gears six 26 are fixedly connected with four reciprocating screw rods 27, the four reciprocating screw rods 27 are in rotary connection with four sliding grooves 5, the four sliding blocks 6 are sleeved on the four reciprocating screw rods 27 in a threaded structure, the bevel gears three 20 rotate to drive the bevel gears four 21 to rotate, the bevel gears four 21 rotate to drive the rotating rod two 23 to rotate, the rotating rod two 23 rotates to drive the bevel gears five 24 to rotate, the bevel gears five 24 rotates to drive the bevel gears six 26 to rotate, the bevel gears six 26 rotate to drive the reciprocating screw rods 27 to rotate, and the reciprocating screw rods 27 rotate to drive the sliding blocks 6 to move back and forth.

Referring to fig. 2 and fig. 4-5, two square cavities 22 and four square cavities three 25 are formed in two sides of the bottom of the shell 1, a bevel gear five 24 and a bevel gear six 26 are located in the square cavities three 25, the square cavities three 25 provide assistance for normal operation of the bevel gear five 24 and the bevel gear six 26, the bevel gears three 20 and the bevel gears four 21 are located in the square cavities two 22, the square cavities two 22 provide assistance for normal operation of the bevel gears three 20 and the bevel gears four 21, the bevel gears one 17 and two 18 are located in the square cavities one 15, and the square cavities one 15 provides assistance for normal operation of the bevel gears one 17 and two 18.

Example 3

Referring to fig. 1 to 5, in the third embodiment of the present utility model, when the present utility model is used, hot water and cold water are respectively added into the first chamber 3 and the second chamber 4 through the water inlet pipe 11, the sealing cover 12 is closed, the heating plate 13 and the refrigerating plate 14 are opened, the heating plate 13 heats the hot water in the second chamber 4, the refrigerating plate 14 refrigerates the cold water in the first chamber 3, the inclined temperature layer body 10 is inserted into the slot 9, the thickness of the partition plate 2 is thinner, the test of the inclined temperature layer body 10 is not affected, the servo motor 16 is opened, the servo motor 16 rotates to drive the bevel gear one 17 to rotate, the bevel gear one 17 rotates to drive the bevel gear two 18 to rotate, the bevel gear two 18 rotates to drive the rotating rod one 19 to rotate, the rotating rod one 19 rotates to drive the bevel gear three 20 to rotate, and the bevel gear three 20 rotates to drive the bevel gear four 21 to rotate, the bevel gear IV 21 rotates to drive the rotating rod II 23 to rotate, the rotating rod II 23 rotates to drive the bevel gear V24 to rotate, the bevel gear V24 rotates to drive the bevel gear V26 to rotate, the bevel gear V26 rotates to drive the reciprocating screw rod 27 to rotate, the reciprocating screw rod 27 rotates to drive the sliding block 6 to move back and forth, the sliding block 6 moves in the sliding groove 5, the sliding block 6 moves to drive the detection plate 7 to move, the detection plate 7 moves to drive the detection head 8 to move, the detection head 8 detects the inclined temperature layer body 10, the detection head 8 moves back and forth up and down to detect, and the accuracy of detection is guaranteed.

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

Claims (6)

1. The utility model provides an energy storage equipment inclined temperature layer testing arrangement, includes casing (1), its characterized in that: the novel intelligent detection device is characterized in that the middle part of the shell (1) is fixedly connected with the partition board (2), a first chamber (3) and a second chamber (4) are formed in two sides of the inner part of the shell (1), four sliding grooves (5) are formed in two sides of the first chamber (3) and the second chamber (4), four sliding grooves (5) are internally connected with four sliding blocks (6) in a sliding mode, two detection boards (7) are fixedly connected with one side of each sliding block (6), two detection boards (7) are mutually close to one side of each detection board and fixedly connected with a plurality of detection heads (8), a groove (9) is formed in the top surface of the partition board (2), and an oblique temperature layer body (10) is inserted into the groove (9).

2. The energy storage device oblique temperature layer testing device according to claim 1, wherein: the top of the first chamber (3) and the top of the second chamber (4) are fixed and communicated with two water inlet pipes (11), and one side of each water inlet pipe (11) is rotatably connected with two sealing covers (12).

3. The energy storage device oblique temperature layer testing device according to claim 1, wherein: one side of the first chamber (3) is fixedly connected with a refrigerating plate (14), and one side of the second chamber (4) is fixedly connected with a heating plate (13).

4. The energy storage device oblique temperature layer testing device according to claim 1, wherein: the novel automatic transmission device is characterized in that a square cavity I (15) is formed in the center of the bottom of the shell (1), a servo motor (16) is fixedly connected inside the square cavity I (15), a bevel gear I (17) is fixedly connected to a rotating shaft of the servo motor (16), two bevel gears II (18) are connected in a meshed mode, two bevel gears II (18) are fixedly connected with one ends of two rotating rods I (19), and two bevel gears III (20) are fixedly connected with the other ends of the rotating rods I (19).

5. The energy storage equipment inclined temperature layer testing device according to claim 4, wherein: two bevel gears three (20) are connected with four bevel gears four (21) in a meshing way, four bevel gears four (21) are fixedly connected with one end of four rotating rods two (23), four rotating rods two (23) are fixedly connected with four bevel gears five (24), four bevel gears five (24) are connected with four bevel gears six (26) in a meshing way, four bevel gears six (26) are fixedly connected with four reciprocating screw rods (27), four reciprocating screw rods (27) are rotationally connected with four sliding grooves (5), and four sliding blocks (6) are sleeved on the threaded structure of the reciprocating screw rods (27).

6. The energy storage equipment inclined temperature layer testing device according to claim 5, wherein: two square cavity two (22) and four square cavity three (25) are arranged on two sides of the bottom of the shell (1), the bevel gear five (24) and the bevel gear six (26) are located inside the square cavity three (25), the bevel gear three (20) and the bevel gear four (21) are located inside the square cavity two (22), and the bevel gear one (17) and the bevel gear two (18) are located inside the square cavity one (15).