CN218451053U - High-efficient radiating distribution automation tester during water-cooling - Google Patents

Abstract

The utility model discloses a distribution automation tester capable of efficiently dissipating heat during water cooling, in particular to the technical field of distribution terminal testers, which comprises a tester body, wherein a plurality of upper cooling pipes are arranged above the outer part of the tester body, and a cooling component is arranged below the outer wall of the tester body; the cooling assembly comprises lower cooling pipes which are arranged below the outer wall of the tester body from left to right in sequence at equal intervals. The utility model discloses a set up the cooling subassembly, the cooling water enters into the reposition of redundant personnel input tube along the screw thread butt joint intraduct, shunt to a plurality of interior cooling tubes of going up through the reposition of redundant personnel input tube, a plurality of interior cooling tubes of going up can carry out the operation of multipoint position cooling to the upper surface position department of tester body, and the inside another part cooling water of reposition of redundant personnel input tube enters into a plurality of under cooling tubes, can continuously carry out outside cooling, reach four face cooling operations, the cooling effect is better, reach high-efficient refrigerated effect.

Description

High-efficient radiating distribution automation tester during water-cooling

Technical Field

The utility model relates to a distribution terminal tester technical field, more specifically says, the utility model relates to a high-efficient radiating distribution automation tester during water-cooling.

Background

In a power distribution system, a power distribution terminal tester is often required to perform current, voltage and test on a power distribution terminal and detect whether the power distribution terminal operates normally.

The utility model patent of patent application publication number CN113804998a discloses a portable power distribution terminal tester, which comprises a testing component, a testing component and side plates, wherein the testing component comprises a tester body and the side plates are arranged on two sides of the tester body; the moving assembly is arranged on the outer side of the side plate and comprises a moving block, a mounting groove arranged on the outer side of the moving block, a limiting part arranged in the mounting groove, a connecting piece matched with the limiting part, positioning pieces arranged on two sides of the moving block and mounting pieces arranged at the top and the bottom of the moving block, wherein the connecting piece is positioned on the outer side of the limiting part. According to the invention, the angle and the inclination of the testing assembly can be adjusted more conveniently by matching the moving assembly and the adjusting assembly, so that a worker can adjust the testing assembly to a proper position in the using process, and the comfort degree of the worker in the working process is greatly improved.

Synthesize above-mentioned patent, when carrying out automated test, because equipment temperature is higher in the testing process, rely on outside hole heat dissipation alone, the radiating effect is relatively poor efficiency, leads to often using in summer because the temperature is too high, causes other electronic components such as magnetic disc tape can cause the recording error because of the effect of heat rising to move unstably, consequently test accuracy is lower.

SUMMERY OF THE UTILITY MODEL

In order to overcome the above-mentioned defect of prior art, the embodiment of the utility model provides a high-efficient radiating distribution automation tester during water-cooling to propose leading to often because the temperature is too high in summer using leading to the fact magnetic disc tape can cause other electronic components such as recording error to move unstablely because of the effect that rises of heat in solving above-mentioned background art, consequently test the lower problem of accuracy.

In order to achieve the above object, the utility model provides a following technical scheme: a distribution automation tester capable of efficiently dissipating heat during water cooling comprises a tester body, wherein a plurality of upper cooling pipes are arranged above the outer part of the tester body, and a cooling assembly is arranged below the outer wall of the tester body;

the cooling subassembly is including setting up the lower cooling tube that from left to right equidistance was arranged in proper order in tester body outer wall below, the one end intercommunication of cooling tube has reposition of redundant personnel input tube and other end intercommunication to collect the conveyer pipe down, one side of reposition of redundant personnel input tube is connected with the screw thread butt joint pipe that is linked together, has the screw thread output tube that is linked together in one side welding that collects the conveyer pipe.

In a preferred embodiment, a plurality of go up the cooling tube from left to right in proper order equidistance range setting, and go up the cooling tube and set up symmetrically between the cooling tube down, it is a plurality of go up the cooling tube and a plurality of cooling tube one-to-one sets up down, and cooling tube and last cooling tube are in same vertical tangent plane position department down, the internal thread has all been seted up to the inner wall of screw thread butt joint pipe and screw thread output tube, and screw thread butt joint pipe and screw thread output tube are made by stainless steel material.

In a preferred embodiment, one side of the tester body is provided with two test sockets for inserting test plugs.

In a preferred embodiment, one side of the shunt input pipe is provided with a stainless steel metal heat preservation frame which is sleeved outside the upper cooling pipes, the inner wall of the stainless steel metal heat preservation frame is bonded with a polyurethane foam frame for heat preservation through a hot melt adhesive, one side of the stainless steel metal heat preservation frame is bonded with a polyurethane foam heat preservation plate, one side of the polyurethane foam heat preservation plate is bonded with a metal cover plate through the hot melt adhesive, the bottom end of the stainless steel metal heat preservation frame is fixedly provided with a lower drainage pipe which is communicated, the outer wall of the lower drainage pipe is in threaded connection with a threaded cover close to the bottom end of the lower drainage pipe, and the bottom end of the stainless steel metal heat preservation frame is provided with support columns for supporting at positions close to three corner lines.

The utility model discloses a technological effect and advantage:

1. by arranging the cooling assembly, cooling water enters the shunting input pipe along the thread butt joint pipe and is shunted to the plurality of upper cooling pipes through the shunting input pipe, the plurality of upper cooling pipes can perform multipoint cooling operation on the upper surface position of the tester body, and another part of cooling water in the shunting input pipe enters the plurality of lower cooling pipes, so that external cooling can be continuously performed, four-surface cooling operation is achieved, the cooling effect is better, and the efficient cooling effect is achieved;

2. stainless steel metal heat preservation frame plays the effect that increases the fastness to polyurethane foam frame, and metal covering plate can play the effect that increases the fastness to polyurethane foam heated board, and polyurethane foam frame and polyurethane foam heated board all can play the thermal-insulated effect of heat preservation to last cooling tube, avoid the low temperature to expand away outward, and the heat preservation effect is better.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is the schematic view of the structure of the stainless steel metal heat preservation frame and the upper cooling pipe split.

Fig. 3 is a schematic view of the bottom view structure of the lower cooling pipe of the present invention.

Fig. 4 is a schematic view of the overall bottom structure of the present invention.

The reference signs are: 1. a tester body; 2. an upper cooling pipe; 3. a lower cooling tube; 4. a shunt input tube; 5. the pipe is butted through screw threads; 6. collecting a conveying pipe; 7. a threaded output pipe; 8. testing the jacks; 9. a stainless steel metal heat preservation frame; 10. a polyurethane foam frame; 11. a polyurethane foam insulation board; 12. a metal cover plate; 13. discharging the pipes; 14. a threaded cap; 15. and (4) a support column.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The distribution automation tester capable of efficiently dissipating heat during water cooling as shown in the attached figures 1-4 comprises a tester body 1, wherein a plurality of upper cooling pipes 2 are arranged above the outer part of the tester body 1, and a cooling component is arranged below the outer wall of the tester body 1;

the cooling assembly comprises lower cooling pipes 3 which are arranged below the outer wall of the tester body 1 from left to right in sequence at equal intervals, one ends of the lower cooling pipes 3 are communicated with a shunting input pipe 4, the other ends of the lower cooling pipes are communicated with a collecting conveying pipe 6, one side of the shunting input pipe 4 is connected with a threaded butt joint pipe 5 which is communicated with the other side of the shunting input pipe 4, and a threaded output pipe 7 which is communicated with the other side of the collecting conveying pipe 6 is welded.

In some embodiments, as shown in fig. 2-3, the plurality of upper cooling pipes 2 are arranged in an equidistant manner from left to right, and the upper cooling pipes 2 and the lower cooling pipes 3 are symmetrically arranged, so that the plurality of upper cooling pipes 2 can cool the upper part of the outer wall of the tester body 1 from left to right, and the person and the lower cooling pipes 3 are symmetrically arranged, the lower cooling pipes 3 can cool the lower part of the outer wall of the tester body 1, the plurality of upper cooling pipes 2 and the plurality of lower cooling pipes 3 are arranged in a one-to-one correspondence manner, and the lower cooling pipes 3 and the upper cooling pipes 2 are located at the same vertical tangent plane position, so that the lower cooling pipes 3 and the one-to-one correspondence manner can uniformly cool the upper part of the outer wall of the tester body 1 and the lower part of the outer wall of the tester body 1, thereby achieving a better cooling effect, the inner walls of the threaded butt-joint pipes 5 and the threaded output pipes 7 are both provided with internal threads, and the threaded butt-joint pipes 5 and the threaded output pipes 7 are made of stainless steel, so that the inner walls of the threaded-joint pipes can be connected to a water outlet pipe of a water tower.

In some embodiments, as shown in fig. 1, two test jacks 8 for inserting test plugs are formed in one side of the tester body 1, so that an equipment connector to be tested is inserted into the internal positions of the two test jacks 8 for positioning insertion, and after the insertion, the tester body 1 with the model number E9382-C1M can be used for power-on testing.

In some embodiments, as shown in fig. 2-4, a stainless steel metal heat-insulating frame 9 sleeved outside a plurality of upper cooling pipes 2 is installed on one side of a shunt input pipe 4, a polyurethane foam frame 10 for heat insulation is bonded on the inner wall of the stainless steel metal heat-insulating frame 9 through a hot melt adhesive, and a polyurethane foam heat-insulating plate 11 is bonded on one side of the stainless steel metal heat-insulating frame 11, and a metal cover plate 12 is bonded on one side of the polyurethane foam heat-insulating plate 11 through a hot melt adhesive, so that when the upper cooling pipes 2 and the lower cooling pipes 3 cool a tester body 1, the polyurethane foam frame 10 and the polyurethane foam heat-insulating plate 11 can play a role in increasing firmness, the metal cover plate 12 can play a role in increasing firmness to the polyurethane foam frame 10, then the polyurethane foam frame 10 and the polyurethane foam heat-insulating plate 11 can both play a role in heat insulation and heat insulation for the upper cooling pipes 2, low-temperature outward expansion is avoided, a better heat-insulating role is played, a cooling effect is ensured, a lower drainage pipe 13 communicated with each other is installed at the bottom of the stainless steel metal heat-insulating frame 9, a polyurethane foam heat-insulating frame 13 is connected to the outer wall of the lower drainage pipe 13 and is connected to the polyurethane foam cover 14 at a position close to the bottom of the polyurethane foam frame, a support column 15, and a screw thread support column 15 capable of supporting the vertical support column for supporting the polyurethane foam frame for supporting the vertical support column, and the polyurethane foam frame 14, so that the vertical foam plate 14 can be separated from the vertical support column, and the vertical support column 1.

The utility model discloses the theory of operation: when the device is used, a connector lug of a device to be tested is inserted into the internal positions of two testing jacks 8, the device is positioned and inserted, the device can be electrified and tested through a tester body 1 with the model of E9382-C1M after being inserted, when the device runs at high temperature in summer, threads on the inner wall of a thread butt joint pipe 5 can be butted on equipment which is normally provided for a factory in a cooling tower, the device is used for a cooling water flow water outlet pipeline, a thread output pipe 7 can be butted on a cooling water tower water return pipeline, the device is connected in a thread mode, cooling water enters a shunt input pipe 4 along the thread butt joint pipe 5, the cooling water is shunted into a plurality of upper cooling pipes 2 through the shunt input pipe 4, the upper cooling pipes 2 can perform multi-point cooling operation on the upper surface position of the tester body 1, another part of the cooling water in the shunt input pipe 4 enters a plurality of lower cooling pipes 3, the lower cooling pipes 3 can perform cooling operation on the lower position of the outer wall of the tester body 1, the cooled water enters the output pipe 7 after entering the output pipe 6, the thread output pipe, the four-side of the lower cooling pipe and the device can achieve the effect of continuous cooling operation of the cooling water return pipeline, the test device, the external cooling water temperature of the device, and the device can be tested, the device, and the device can effectively prevent the temperature from being collected on the external high-temperature test effect of the test instrument when the test instrument.

The points to be finally explained are: first, in the description of the present application, it should be noted that, unless otherwise specified and limited, the terms "mounted," "connected," "connecting," and "connecting" should be understood broadly, and may be a mechanical connection or an electrical connection, or a communication between two elements, and may be directly connected, and "upper," "lower," "left," and "right" are only used to indicate relative positional relationships, and when the absolute position of the object to be described is changed, the relative positional relationships may be changed;

secondly, the method comprises the following steps: in the drawings of the disclosed embodiments of the present invention, only the structures related to the disclosed embodiments are referred to, and other structures can refer to the common design, and under the condition of no conflict, the same embodiment and different embodiments of the present invention can be combined with each other;

and finally: the above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The utility model provides a high-efficient radiating distribution automation tester during water-cooling, includes tester body (1), a plurality of cooling tubes (2), its characterized in that are gone up are installed to the outside top of tester body (1): a cooling component is arranged below the outer wall of the tester body (1);

the cooling subassembly is including setting up lower cooling tube (3) that from left to right arrange in proper order equidistance in tester body (1) outer wall below, the one end intercommunication of cooling tube (3) has reposition of redundant personnel input tube (4) and other end intercommunication to collect conveyer pipe (6) down, one side of reposition of redundant personnel input tube (4) is connected with the screw thread butt joint pipe (5) that are linked together, has screw thread output tube (7) that are linked together in the one side welding that collects conveyer pipe (6).

2. The distribution automation tester of claim 1, high-efficient heat dissipation when water-cooling, characterized in that: a plurality of the upper cooling pipes (2) are arranged in sequence at equal intervals from left to right, and the upper cooling pipes (2) and the lower cooling pipes (3) are symmetrically arranged.

3. The distribution automation tester capable of efficiently dissipating heat during water cooling of claim 1, characterized in that: the upper cooling pipes (2) and the lower cooling pipes (3) are arranged in a one-to-one correspondence mode, and the lower cooling pipes (3) and the upper cooling pipes (2) are located at the same vertical section position.

4. The distribution automation tester capable of efficiently dissipating heat during water cooling of claim 1, characterized in that: the inner walls of the thread butt joint pipe (5) and the thread output pipe (7) are provided with internal threads, and the thread butt joint pipe (5) and the thread output pipe (7) are made of stainless steel materials.

5. The distribution automation tester of claim 1, high-efficient heat dissipation when water-cooling, characterized in that: two test jacks (8) used for inserting test plugs are formed in one side of the tester body (1).

6. The distribution automation tester of claim 1, high-efficient heat dissipation when water-cooling, characterized in that: the utility model discloses a cooling tube, including reposition of redundant personnel input tube (4), the stainless steel metal heat preservation frame (9) of establishing a plurality of cooling tube (2) outsides are gone up to the cover is installed to one side of reposition of redundant personnel input tube (4), and it has polyurethane foam frame (10) and one side bonding that are used for heat preservation to bond through the hot melt adhesive at the inner wall of stainless steel metal heat preservation frame (9) has polyurethane foam heated board (11), and there is metal decking (12) polyurethane foam heated board (11) one side through the hot melt adhesive bonding.

7. The distribution automation tester capable of efficiently dissipating heat during water cooling of claim 6, characterized in that: the bottom end of the stainless steel metal heat-insulating frame (9) is fixedly provided with a lower row of communicated pipes (13), the outer wall of the lower row of pipes (13) is in threaded connection with a threaded cover (14) close to the bottom end of the lower row of pipes, and the bottom end of the stainless steel metal heat-insulating frame (9) is provided with support columns (15) used for supporting the bottom end of the stainless steel metal heat-insulating frame and close to the three corner line positions.

Images