CN203422389U - High voltage load test impedance device - Google Patents
High voltage load test impedance device Download PDFInfo
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- CN203422389U CN203422389U CN201320548230.2U CN201320548230U CN203422389U CN 203422389 U CN203422389 U CN 203422389U CN 201320548230 U CN201320548230 U CN 201320548230U CN 203422389 U CN203422389 U CN 203422389U
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Abstract
The utility model discloses a high voltage load test impedance device. The high voltage load test impedance device is connected in series with a test loop of an electrical appliance to carry out load adjusting, the test loop has two access points, the high voltage load test impedance device is characterized by comprising one or multiple series impedance units and an insulation support used for bearing the impedance unit, the impedance unit comprises an input end, N impedance elements, N+1 switching ends and an output end, the input end and the N impedance elements are connected in series sequentially, and the N+1 switching ends are respectively connected with the input end and output sides of the N impedance elements. According to the high voltage load test impedance device, multiple impedance values can be realized through adjusting, so multiple requirements of high voltage load tests can be met, adjustment of the impedance values is convenient to realize, equipment cost can further be effectively reduced, a casing of the high voltage load test impedance device employs a complete insulation structure, so influence of a metal structure member on a resistor element and an induction element is avoided.
Description
Technical Field
The utility model relates to an impedance device, concretely relates to high-voltage load test's impedance device.
Background
The electric appliance test is used for verifying various performances of the electric appliance under normal working and fault conditions, and the electric appliance has various high-voltage and low-voltage electric appliances, wide application, complex use conditions and more comprehensive effects of factors such as electricity receiving, mechanical force, heat generation and the like under various natural environment conditions, so that the performance index and the working reliability of the electric appliance must be verified by using a verification method.
The existing electric appliance tests are divided into high-voltage electric appliance tests and low-voltage electric appliance tests, and both the high-voltage electric appliance and the low-voltage electric appliance have various different specifications and performance parameter requirements, so that various test loops are often required to be designed when the electric appliances with different specifications are tested, each loop is provided with different impedance devices, and therefore a plurality of impedance devices must be designed and manufactured, a large amount of funds and test sites are required, test loops are required to be frequently replaced, and the requirements of environmental protection and energy conservation are not met. In addition, because the voltage of the high-voltage electrical apparatus is high, the requirement on the insulation performance of the high-voltage electrical apparatus is also high, absolute insulation is also required for the test environment of the high-voltage electrical apparatus when the high-voltage electrical apparatus is tested, and the conventional high-voltage electrical apparatus cannot meet the requirement on complete insulation often when the high-voltage electrical apparatus is tested.
SUMMERY OF THE UTILITY MODEL
The utility model aims to solve the technical problem that a high-voltage load test's impedance device that can be used for adjusting test current, power factor and time constant when electrical products are experimental is provided.
The utility model discloses a following technical scheme realizes: an impedance device for a high-voltage load test is connected in series in a test loop of an electric product for load adjustment, the test loop is provided with two access points, the impedance device comprises one or a plurality of impedance units which are connected in series and an insulating bracket which is used for bearing the impedance units, each impedance unit comprises an input end, N impedance elements, N +1 switching ends and an output end, and the input end and the N impedance elements are sequentially connected in series; the N +1 switching ends are respectively connected to the input end and the output sides of the N impedance elements; the output end is connected with the N +1 switching ends in a switching way and is connected with the input end of one access point or the adjacent impedance unit; the input end is connected with the output end of another access point or the adjacent impedance unit.
Furthermore, the insulating support comprises a vertically arranged panel, side plates symmetrically arranged at two sides of the panel, shelves fixedly connected with the panel and the side plates and porcelain bottle bottom columns used for supporting the panel and the side plates; a gap is arranged between the panel and the side plate, and the panel and the side plate are epoxy plates; the shelves are epoxy shelves.
Further, the switching end is provided with a switching contact; the output end is provided with a switching copper bar; the switching copper bar is in switching connection with the switching contact; the switching contact and the switching copper bar are both arranged on the panel; the output end is connected with the input end of one access point or the adjacent impedance unit through a connecting copper bar; the input end is connected with the output end of another access point or the adjacent impedance unit through a connecting copper bar; and the adjacent impedance units are connected through a connecting copper bar.
Further, the impedance elements in each impedance unit are inductance elements and/or resistance elements, and the impedance elements in adjacent impedance units are all inductance elements or all resistance elements or are inductance elements and resistance elements respectively.
Further, the inductance element comprises a plurality of air-core coils which are connected in series and coaxially stacked, a clamping plate which bears and clamps the plurality of air-core coils, and a backing plate which is arranged between the adjacent air-core coils.
Furthermore, a plurality of cushion blocks are arranged at intervals along the radial line direction of each air-core coil, and the cushion blocks are made of epoxy glass materials.
Furthermore, polyester film and paper for insulation are coated on the outer side of the lead of the hollow coil, and the wound hollow coil is also soaked with a paint layer.
Furthermore, a tap of each air-core coil is arranged on the outer side of the air-core coil, and a tap of an adjacent air-core coil is clamped and fixed through a wire clamp.
Furthermore, the resistance element comprises a resistance support and an iron-chromium-aluminum high-resistance metal strip which is wound on the resistance support in an S-shaped reciprocating manner; the resistor support is made of epoxy glass material; and a ceramic clamping block for high temperature resistance is arranged between the layers of the iron-chromium-aluminum high-resistance metal belt.
Further, the outer surface of the porcelain clamp block is coated with a glaze layer.
The beneficial effects of adopting the technical scheme are as follows.
The impedance device of the high-voltage load test is used as the adjusting load of the on-off capacity, the dynamic thermal stability test and the electric service life test of the high-voltage electrical appliance, is widely applied to electrical appliance laboratories, scientific research institutions, quality supervision and inspection centers, enterprise research and development centers and test stations, is connected in series with a test loop of a high-voltage electrical appliance product, is used for adjusting test current and power factors during the test of the alternating-current electrical appliance, and is used for adjusting the test current and time constant during the test of the direct-current electrical appliance; a plurality of impedance values can be adjusted by each impedance device, the requirement of the impedance values of test loops of various electrical appliances is met, and the shell of the impedance device for the high-voltage load test adopts a full-insulation structure, so that the influence of a metal structural member on a resistance element and an inductance element is avoided.
The insulating support selects the epoxy plate as the panel and the side plate, and is connected with the nylon fastener by using the epoxy shelves, so that the insulating level of the insulating support is improved.
The coil of the inductance element is a cake-shaped hollow coil, and a base plate is additionally arranged among layers, so that the insulation level and the structural strength of the hollow coil are improved.
The hollow coil is provided with a cushion block used for isolating the inner ring and the outer ring of the coil along the radial line direction of the hollow coil, and the cushion block is made of epoxy glass materials, so that the insulating property of the hollow coil is improved.
The wire of the hollow coil is coated and insulated by polyester film and paper, and the coil is subjected to secondary vacuum drying and paint dipping after being wound.
The taps of the hollow coil are arranged on the side face right in front of the outside of the hollow coil, and the taps of the coil are fixed by a wire clamp and are convenient to connect.
The resistance element is made of 0Cr25Al5 iron chromium aluminum high resistance metal belt with low temperature coefficient. The winding of each resistance element adopts the structure that circulates to and fro to minimize the inductance of the resistance element, and the iron-chromium-aluminum high-resistance metal bands are isolated by high-temperature-resistant porcelain blocks, and the porcelain blocks are glazed to prevent the insulation from being affected by moisture due to condensation, and the resistance support adopts epoxy glass materials to avoid the discharge of high voltage to metal materials.
Drawings
Fig. 1 is a front view of an impedance device 1 of a high-voltage load test of the present invention;
fig. 2 is a side view of the impedance device of embodiment 1 of the high voltage load test of the present invention;
fig. 3 is a circuit diagram of an impedance unit in embodiment 1 of the impedance device for high voltage load test disclosed in the present invention;
fig. 4 is a schematic structural diagram of an inductance element in embodiment 2 of the impedance device for high voltage load test disclosed in the present invention;
fig. 5 is a schematic structural diagram of an inductance element in embodiment 3 of the impedance device for high voltage load test disclosed in the present invention;
fig. 6 is a front view of the impedance device of embodiment 5 of the high voltage load test of the present invention;
fig. 7 is a side view of the impedance device of embodiment 5 of the high voltage load test of the present invention;
fig. 8 is a circuit diagram of an impedance unit in an embodiment 5 of the impedance device for high voltage load test disclosed in the present invention;
fig. 9 is a front view of the impedance device of embodiment 7 of the high voltage load test of the present invention;
fig. 10 is a side view of the impedance device of embodiment 7 of the high voltage load test of the present invention;
fig. 11 is a circuit diagram of an impedance unit in embodiment 7 of the impedance device for high voltage load test disclosed in the present invention;
fig. 12 is a front view of an impedance device of an embodiment 8 of the high voltage load test of the present invention;
fig. 13 is a side view of the impedance device of embodiment 8 of the high voltage load test of the present invention;
fig. 14 is a circuit diagram of an impedance unit in an embodiment 8 of the impedance device for high voltage load test disclosed in the present invention;
fig. 15 is a front view of the impedance device of embodiment 9 of the high voltage load test of the present invention;
fig. 16 is a side view of the impedance device of embodiment 9 of the high voltage load test of the present invention;
fig. 17 is a circuit diagram of an impedance unit in an embodiment 9 of the impedance device for high voltage load test disclosed in the present invention;
fig. 18 is a front view of an embodiment 10 of the impedance device for high voltage load testing of the present invention;
fig. 19 is a circuit diagram of an impedance unit in embodiment 10 of the impedance device for high voltage load test disclosed in the present invention.
Wherein,
1. test loop 11, access point 21, input terminal 22, inductive element 23, switching terminal 24, output terminal 25, shunt resistor 31, panel 32, side plate 33, shelf 34, bottom column of porcelain bottle
K01, K1, K2, K3, K02, K4, K5, K6. switching contacts
P1. connecting copper bar
P2, P3. switching copper bar
A. Impedance device b in example 7 impedance device c in example 8 impedance device in example 9.
Detailed Description
Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings.
Example 1
Referring to fig. 1-3, as shown in the drawings, an impedance device for high voltage load test is connected in series in a test loop 1 of an electrical product for load adjustment, the test loop 1 has two access points 11, the impedance device includes an impedance unit and an insulating bracket for carrying the impedance unit, the impedance unit includes an input end 21, three inductive elements 22, four switching ends 23 and an output end 24, the input end 21 and the three inductive elements 22 are connected in series in sequence; the four switching terminals 23 are respectively connected to the input terminal 21 and the output sides of the three inductance elements 22; the output terminal 24 is connected with the four switching terminals 23 in a switching way and connected with one access point 11; the input 21 is connected to another access point 11.
A shunt resistor 25 is also connected in parallel to each inductive element 22.
The insulating bracket comprises a panel 31 vertically arranged, side plates 32 symmetrically arranged at two sides of the panel 31, shelves 33 fixedly connecting the panel 31 and the side plates 32, and a porcelain bottle bottom column 34 for supporting the panel 31 and the side plates 32; the panel 31 and the side plate 32 have a gap therebetween and are both epoxy plates; the shelves 33 are epoxy shelves.
The input end 21 and the output end 24 are respectively and correspondingly connected with the two access points 11 through connecting copper bars P1.
The inductances of the three inductance elements 22 are 1L, 2L and 3L, the four switching terminals 23 are provided with switching contacts K01, K1, K2 and K3, respectively, and the output terminal 24 is provided with a switching copper bar P2; when the switching copper bar P2 is in contact with the switching contact K01, no inductor is connected into the test loop, when the switching copper bar P2 is in contact with the switching contact K1, the inductor 1L is connected into the test loop, when the switching copper bar P2 is in contact with the switching contact K2, the inductor 2L is connected into the test loop, and when the switching copper bar P2 is in contact with the switching contact K3, the inductor 3L is connected into the test loop.
The switching contacts K01, K1, K2, K3 and the switching copper bar P2 are all mounted on the outer side of the panel 31, and the remaining components are housed and mounted in the open space between the side plates 32.
The impedance device of the high-voltage load test in the embodiment is used as an adjusting load for the on-off capacity, the dynamic thermal stability test and the electrical life test of the high-voltage electrical appliance, is widely applied to electrical appliance laboratories, scientific research institutions, quality supervision and inspection centers, enterprise research and development centers and test stations, is connected in series in a test loop of a high-voltage electrical appliance product, is used for adjusting test current and power factors during an alternating-current electrical appliance test, and is used for adjusting test current and time constant during a direct-current electrical appliance test; a plurality of impedance values can be adjusted by each impedance device, the requirements of the impedance values of test loops of various electrical appliances are met, the shell of the impedance device for the high-voltage load test adopts a full-insulation structure, the influence of a metal structural member on an inductance element is avoided, and the insulation support is connected by an epoxy plate and an epoxy shelf through a nylon fastener, so that the insulation level of the insulation support is improved.
Example 2
Referring to fig. 4, as shown in the figure, the rest is the same as the embodiment 1 except that the inductance component 22 includes four air-core coils 221 connected in series and coaxially stacked, two clamping plates 222 carrying and clamping four layers of air-core coils, and three pads 223 disposed between the adjacent air-core coils 221, and the output end of each air-core coil 221 is disposed outside the air-core coil 221 and clamped and fixed by a wire clamp 224.
The coil of the inductance element is an air core coil 221 with a cake-shaped structure, a backing plate 223 is added among layers, the insulation level and the structural strength of the air core coil 221 are improved, a tap of the air core coil 221 is arranged on the right front side face outside the air core coil, and the air core coil is fixed by a wire clamp 224 and is convenient to connect.
Example 3
Referring to fig. 5, as shown in the figure, the rest is the same as the example 2, except that a plurality of spacers 225 are further disposed at intervals along the radial line direction of the air-core coil 221, and the spacers 225 are made of epoxy glass material.
The air-core coil 221 is provided with a cushion block 225 along the radial line direction for isolating the inner and outer coils of the coil, and the cushion block is made of epoxy glass materials, so that the insulating property of the air-core coil 221 is improved.
Example 4
The rest of the coil is the same as the embodiment 2, except that the outside of the lead of the hollow coil is coated with polyester film and paper for insulation, and the wound coil is also impregnated with a paint layer.
The wire of the hollow coil is coated and insulated by polyester film and paper, and the coil is subjected to secondary vacuum drying and paint dipping after being wound.
Example 5
Referring to fig. 6 to 8, as shown in the drawings, the same as in embodiment 1 is applied, except that the inductive element is replaced by a resistive element 26, and the resistive element 26 does not need to be connected in parallel with the shunt resistor.
The resistances of the three resistance elements are respectively 1R, 2R and 3R, the four switching ends 23 are respectively provided with switching contacts K02, K4, K5 and K6, and the output end 24 is provided with a switching copper bar P3; when the switching copper bar P3 is in contact with the switching contact K02, no resistor is connected into the test loop, when the switching copper bar P3 is in contact with the switching contact K4, the resistor 1R is connected into the test loop, when the switching copper bar P3 is in contact with the switching contact K5, the resistor 2R is connected into the test loop, and when the switching copper bar P3 is in contact with the switching contact K6, the resistor 3R is connected into the test loop.
The impedance device of the high-voltage load test in the embodiment is used as an adjusting load for the on-off capacity, the dynamic thermal stability test and the electrical life test of the high-voltage electrical appliance, is widely applied to electrical appliance laboratories, scientific research institutions, quality supervision and inspection centers, enterprise research and development centers and test stations, is connected in series in a test loop 1 of a high-voltage electrical appliance product, is used for adjusting test current and power factors during an alternating-current electrical appliance test, and is used for adjusting test current and time constant during a direct-current electrical appliance test; the housing of the impedance device for the high-voltage load test adopts a full-insulation structure, so that the influence of a metal structural member on the resistance element 26 is avoided, and the insulation support is connected by an epoxy plate and an epoxy shelf through a nylon fastener, so that the insulation level of the insulation support is improved.
Example 6
The rest is the same as the embodiment 5, except that the resistance element comprises a resistance support and an iron-chromium-aluminum high-resistance metal strip circularly and reciprocally wound on the resistance support in an S shape; the resistor support is made of epoxy glass material; and a ceramic clamping block for high temperature resistance is arranged between the layers of the iron-chromium-aluminum high-resistance metal belt.
Further, the outer surface of the porcelain clamp block is coated with a glaze layer.
The resistance element is made of 0Cr25Al5 iron chromium aluminum high resistance metal belt with low temperature coefficient. The winding of each resistance element adopts a circulating structure to reduce the inductance of the resistance element as much as possible; the iron-chromium-aluminum high-resistance metal strips are isolated by high-temperature-resistant porcelain clamping blocks, the porcelain clamping blocks are glazed to prevent the insulation from being affected by moisture due to condensation, and the resistance support is made of epoxy glass materials to avoid discharge of high voltage to metal materials.
Example 7
Referring to fig. 9 to 11, the rest is the same as that of the embodiment 3 or 4 as illustrated in the legend thereof, except that the above-described impedance device includes two impedance units connected in series.
One of the inputs 21 of the first impedance unit is connected to one of the access points 11, the output 24 of the first impedance unit is connected to one of the inputs 21 of the second impedance unit, and the output 24 of the second impedance unit is connected to the other access point 11.
Example 8
Referring to fig. 12 to 14, the same as the embodiment 7 except that the impedance device includes two impedance units connected in series as illustrated therein.
One of the inputs 21 of the first impedance unit is connected to one of the access points 11, the output 24 of the first impedance unit is connected to one of the inputs 21 of the second impedance unit, and the output 24 of the second impedance unit is connected to the other access point 11.
Example 9
Referring to fig. 15 to 17, as shown in the legends thereof, the impedance device in the present embodiment includes the impedance device in embodiment 3 or 4 and the impedance device in embodiment 7, and the impedance device in embodiment 3 or 4 and the impedance device in embodiment 7 are connected in series.
Example 10
Referring to fig. 18 to 19, as shown in the legends thereof, the impedance device in the present embodiment includes an impedance device a in embodiment 7, an impedance device B in embodiment 8, and an impedance device C in embodiment 9, and the impedance device a in embodiment 7, the impedance device B in embodiment 8, and the impedance device C in embodiment 9 are sequentially connected in series.
The setting of above-mentioned impedance device's impedance unit sets up according to particular case, and its multiple setting condition all belongs to the utility model discloses a protection scope.
The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, many modifications and improvements can be made without departing from the inventive concept, and all of them belong to the protection scope of the present invention.
Claims (10)
1. An impedance device for a high-voltage load test is connected in series in a test loop of an electric product for load adjustment, the test loop is provided with two access points, the impedance device is characterized by comprising one or a plurality of impedance units which are connected in series and an insulating bracket used for bearing the impedance units, each impedance unit comprises an input end, N impedance elements, N +1 switching ends and an output end, and the input end and the N impedance elements are sequentially connected in series; the N +1 switching ends are respectively connected to the input end and the output sides of the N impedance elements; the output end is connected with the N +1 switching ends in a switching way and is connected with the input end of one access point or the adjacent impedance unit; the input end is connected with the output end of another access point or the adjacent impedance unit.
2. The impedance device according to claim 1, wherein the insulating bracket comprises a vertically arranged panel, side plates symmetrically arranged at two sides of the panel, shelves fixedly connected with the panel and the side plates and porcelain insulator bottom columns used for supporting the panel and the side plates; a gap is arranged between the panel and the side plate, and the panel and the side plate are epoxy plates; the shelves are epoxy shelves.
3. Impedance device according to claim 2, characterized in that the switching end is provided with a switching contact; the output end is provided with a switching copper bar; the switching copper bar is in switching connection with the switching contact; the switching contact and the switching copper bar are both arranged on the panel; the output end is connected with the input end of one access point or the adjacent impedance unit through a connecting copper bar; the input end is connected with the output end of another access point or the adjacent impedance unit through a connecting copper bar; and the adjacent impedance units are connected through a connecting copper bar.
4. An impedance device according to any one of claims 1-3, wherein the impedance elements in each of the impedance units are inductive elements and/or resistive elements, and the impedance elements in adjacent impedance units are inductive elements or resistive elements or inductive elements and resistive elements, respectively.
5. The impedance device of claim 4, wherein said inductive element comprises a plurality of air-core coils connected together in series and arranged coaxially in a stack, a clamping plate carrying and clamping said plurality of air-core coils, and a backing plate disposed between adjacent ones of said air-core coils.
6. The impedance device according to claim 5, wherein each of the air-core coils is further provided with a plurality of spacers at intervals along a radial line direction thereof, and the spacers are made of epoxy glass material.
7. The impedance device according to claim 5, wherein the outer side of the wire of the air-core coil is coated with mylar and paper for insulation, and the wound air-core coil is further impregnated with a paint layer.
8. The impedance device according to claim 5, wherein a tap of each of the air-core coils is disposed outside the air-core coil, and a tap of an adjacent air-core coil is held and fixed by a wire clamp.
9. The impedance device according to claim 4, wherein the resistance element comprises a resistance support and an iron-chromium-aluminum high-resistance metal strip wound on the resistance support in an S-shaped circular reciprocating manner; the resistor support is made of epoxy glass material; and a ceramic clamping block for high temperature resistance is arranged between the layers of the iron-chromium-aluminum high-resistance metal belt.
10. The impedance device of claim 9, wherein the outside of the porcelain clip piece is coated with an enamel layer.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201320548230.2U CN203422389U (en) | 2013-09-05 | 2013-09-05 | High voltage load test impedance device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201320548230.2U CN203422389U (en) | 2013-09-05 | 2013-09-05 | High voltage load test impedance device |
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| Publication Number | Publication Date |
|---|---|
| CN203422389U true CN203422389U (en) | 2014-02-05 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201320548230.2U Expired - Lifetime CN203422389U (en) | 2013-09-05 | 2013-09-05 | High voltage load test impedance device |
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| CN (1) | CN203422389U (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103439534A (en) * | 2013-09-05 | 2013-12-11 | 苏州安泰变压器有限公司 | Impedance device for high-voltage load test |
-
2013
- 2013-09-05 CN CN201320548230.2U patent/CN203422389U/en not_active Expired - Lifetime
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103439534A (en) * | 2013-09-05 | 2013-12-11 | 苏州安泰变压器有限公司 | Impedance device for high-voltage load test |
| CN103439534B (en) * | 2013-09-05 | 2016-04-20 | 苏州安泰变压器有限公司 | A kind of impedance means of high-voltage load test |
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| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| AV01 | Patent right actively abandoned |
Granted publication date: 20140205 Effective date of abandoning: 20160420 |
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