US2130995A - Refrigerating apparatus - Google Patents
Refrigerating apparatus Download PDFInfo
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- US2130995A US2130995A US721512A US72151234A US2130995A US 2130995 A US2130995 A US 2130995A US 721512 A US721512 A US 721512A US 72151234 A US72151234 A US 72151234A US 2130995 A US2130995 A US 2130995A
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- evaporator
- compressor
- compartment
- air
- motor
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B49/00—Arrangement or mounting of control or safety devices
- F25B49/02—Arrangement or mounting of control or safety devices for compression type machines, plants or systems
- F25B49/025—Motor control arrangements
Definitions
- This invention relates to refrigeration, and more particularly to the conditioning of air.
- the figure is a representation, partly in crosssection and partly diagrammatic, of an air conditioning apparatus embodying features of my invention.
- air for the compartment I0 is brought in thermal contact with an evaporator II.
- the air is caused to flow in the form of an air stream by an electrically driven blower l2 which causes the stream of air to flow from the enclosure ill (or from the outside, or both) through the inlet
- the refrigerant evaporator II is in refrigeran flow relationship with a refrigerant liquefying unit I6.
- this unit takes the form of a compressor I'l, condenser l8, and a liquid refrigerant receiver IS.
- the refrigerant liquefied by this unit flows through the liquid line to the 35 evaporator II, and the evaporated refrigerant returns from the evaporator through the line 2
- the evaporator is provided with an automatic expansion valve 22 which tends to feed 40 liquid refrigerant into the evaporator II when the refrigerant pressure therein falls below a predetermined limit.
- this valve 22 is also controlled by a thermostatic bulb 23 placed adjacent the outlet of evaporator, and this bulb 23 45 throttles the valve 22 whenever liquid refrigerant 55 The arrangement is such that the'speed of the decrease when that temperature decreases.
- compressor i1 is automatically increased when the temperature created by the evaporator I increases, and the speed of the compressor tends to This is accomplished by providing a temperature responsive means 26, responsive either to dry bulb temperatures or wet bulb temperatures, or both, inthe compartment ill, which automatically varies the setting of the speed responsive device 25 to accomplish this purpose.
- the bulb 26 is connected by a pipe 21 with an expansion bellows 28 adjacent the transmission 25.
- the belt 34 forces the flanges 36 and 31 of the pulley 38 on the compressor i'l outwardly against the spring 38a and reduces the effective diameter of the pulley on the compressor shaft. This increases the speed of the compressor as the temperature in the compartment 0 rises. When the temperature in the compartment l0 decreases the converse operation occurs and the speed of the compressor is accordingly decreased.
- the variable speed transmission 25 may take any desired form, but as abovedescribed, the form shown is now preferred.
- the cone 29 is slidably keyed at 39 so that the same may slide axially on the-shaft 35, but must rotate therewith.
- are mounted on the sleeve 40 which is flxed on the shaft 35 through the hub 4
- the flange 32 is slidably mounted on the hub 4
- the levers 30 are provided with a flexible band 45 which tends to contract the right hand ends of the levers against the cone 29.
- a lever 48 is fulcrumed at 41 with one end in an engagement with the bellows 28 and is provided at the other end with an anti-friction roller 48 incontact with the cone 29.
- the motor 24, and consequently the compressor I1 is caused to start and stop automatically in response to temperature conditions in the compartment ID.
- This is accomplished by providing a thermostatic switch 50 with its temperature response element 5
- This switch may be responsive to dry bulb, or wet bulb temperatures, or both'fi.
- the switch causes the motor 24 to'start when the temperature in the compart ment i0 'rises ove a predetermined limit, and causes the moto to stop when temperature falls below a predetermined limit.
- Both of these limits are preferably near thelower range of comfort temperature, so that the compressor starts to operate when the temperature rises sufficiently to require air conditioning and so that the compressor, stops when the temperature falls near the lower comfort range when no refrigeration is required.
- the various parts of the apparatus are so calibrated that the refrigerant temperatures of the evaporator II are maintained sumciently low to create comfort conditions in the compartment to, but the refrigerant temperatures are maintained sufliciently high to prevent thefreezing of moisture from the. stream of air passing through compartment I4 on the evaporator.
- the temperature may be sufllciently low to condense moisturefrom the air, but not to freeze it. Any moisture thus condensed may accumulate in being drained from the pan 52 placed below the evaporator ll.
- the switch 50 causes the. motor 24 to operate.
- the temperature responsive means 28 then actuates the lever 16 to the proper position' to insure the proper speed of rotation of the compressor shaft.
- the means 26 may be manually set so that the apparatus tends to maintain higher or lower temperatures.
- the nuts 53 and 54 may be tumed'against the fixed stop 55 to vary the tension on the spring evaporator, an electric motor, means controlling the operation of said motor in accordance with temperature conditions, a variable speed mechanical connection between said motor and unit and means for controlling said variable speed connection in accordance with air conditions in said compartment.
- An air conditioning apparatus comprising a compartment to be cooled, an evaporator for cooling air for said compartment, av refrigerant .f'lique'fying unit operatively connected to said evaporator, an electric motor, means for starting and stopping said motor automatically in accordance with refrigeration demands, a var-v iable speed mechanical connection between said motor and unit and means for controlling said compartment to be cooled, an evaporator for cooling air for said compartment, a refrigerant liquefying unit including a compressor and condenser operatively connected to said evaporator,
- Anair conditioning apparatus comprising a compartment to be cooled, an evaporator for cooling air for said compartment, a refrigerant liquefying unit including a compressor and condenser operatively connected to said evaporator, an electric motor, an element responsive to conditions in said compartment controlling the operation of said motor, a variable speed mechanical connection between said motor and unit and means for controlling said variable speed connection in accordance with the cooling effect of said evaporator on air in said-compartment.
- An air conditioning apparatus comprising a compartment to be cooled, an evaporator for cooling air for said compartment, a refrigerant liquefying unit operatively connected to said evaporator, a constant speed electric motor, means for automatically starting said motor in accordance with refrigeration demands, a variable speed mechanical connection'between said, motor and unit and means for controlling said variable speed connection in accordance with the cooling eflectofi said evaporator on air in said compartment.
- An air conditioning apparatus comprising an evaporator, compressor and condenser in refrigerant flow relationship, a constant speed electric motor, a mechanical transmission between said motor and compressor, means controlling the operation, of said motor in accordance with refrlgeration demands and means automatically responsive to temperature conditions created by said evaporator to, increase-the speed of said compressor when the temperature increases and to decreaselthespeed of said compressor when the. temperature decreases, said means including a mechanical variable ratio drive and a thermostat actuating said drive to vary the driving ratio, said thermostat being independent of evaporator temperatures.
- An air conditioning apparatus comprising an evaporator, compressor and condenser in refrigerant flow relationship, a fan for blowing air over said evaporator, a motor driving said fan, a constant speed electric compressor motor, a mechanical transmission between said compressor motor and compressor, and means automatically responsive ⁇ to air temperature conditions ore--55 ated by said evaporator to adjust said transmistric motor, a mechanical transmission between ,7
- said motor and compressor means automatically responsive to air temperature conditions created by said evaporator to adjust said transmission to increase the speed oi said compressor when the air temperature increases and to decrease the speed of said compressor when the air tempera- 7o ture decreases, and means responsive to temperature conditions created by said evaporator for starting and stopping said motor.
- An air conditioning-apparatus comprising an evaporator, compressor and condenser in re- 75..
- a fan for blowing air over said evaporator a constant speed electric motor, a mechanical transmission between said motor and compressor, means automatically responsive to air temperature conditions created by said evaporator to adjust said transmission to increase the spied of said compressor when the air temperature increases and to decrease the speed of said compressor when the air temperature decreases and means responsive to temperature conditions created by said evaporator for starting and stopping said motor.
- An air cooling apparatus comprising a compartment to be cooled, an evaporator cooling air for said compartment, a compressor and condenser connected to-said evaporator in refrigerant flow relationship, an electric motor, a variable ratio drive between said motor and compressor, and means for adjusting said drive in accordance with air conditions in said compartment.
- An air cooling apparatus comprising a compartment to be cooled, an evaporator cooling air for said compartment, a compressor and condenser connected to said evaporator in refrigerant flow relationship, an electric motor, a variable ratio drive between said motor and compressor, and means for adjusting said drive in accordance with air conditions in said compartment, said drive and adjusting means comprising a driven compressor V-pulley, spring means urging the sides of said V-pulley together, a motor driving V-pulley, a belt between said pulleys, and thermostatic means varying the distance between the sides of said driving V-pulley.
- An air conditioning apparatus comprising a compartment to be cooled, an evaporator for, cooling air Ior said compartment, a refrigerant liquei'ying unit including a compressor and condenser operatively connected to said evaporator, an electric motor, a thermostatic switch controlling the operation of said motor, a variable speed mechanical connection between said motor and compressor, and means for controlling said variable speed connection in accordance with temperature conditions of air at a point within said compartment remote from said evaporator.
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- Engineering & Computer Science (AREA)
- Physics & Mathematics (AREA)
- Mechanical Engineering (AREA)
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- General Engineering & Computer Science (AREA)
- Air Conditioning Control Device (AREA)
Description
Sept. 20, 1938. c. F. HENNEY REFRIGERATING APPARATUS Filed April 20, 1934 Patented Sept. 20, 1938 UNITED STATES PATENT OFFICE 2,130,995 REFRIGERATING APPARATUS Application April 20, 1934, Serial No. 721,512
12 Claims.
This invention relates to refrigeration, and more particularly to the conditioning of air.
It is among the objects of this invention to provide apparatus for conditioning air in which even 6 temperatures are maintained and in which objectionable frequent starting and stopping of the refrigerant liquefying unit is avoided.
Further objects and advantages of the present invention will be apparent from the following description reference being had to the accompanying drawing, wherein a preferred form of the present invention is clearly shown.
In the drawing: a
The figure is a representation, partly in crosssection and partly diagrammatic, of an air conditioning apparatus embodying features of my invention.
In practicing my invention, air for the compartment I0 is brought in thermal contact with an evaporator II. The air is caused to flow in the form of an air stream by an electrically driven blower l2 which causes the stream of air to flow from the enclosure ill (or from the outside, or both) through the inlet |3 into the air condition-,
25 ing casing or compartment H where it is brought in thermal contact with the evaporator II and from which it is discharged through the outlet l5 into the compartment in. v
The refrigerant evaporator II is in refrigeran flow relationship with a refrigerant liquefying unit I6. Preferably this unit takes the form of a compressor I'l, condenser l8, and a liquid refrigerant receiver IS. The refrigerant liquefied by this unit flows through the liquid line to the 35 evaporator II, and the evaporated refrigerant returns from the evaporator through the line 2| to the compressor l'l.
Preferably the evaporator is provided with an automatic expansion valve 22 which tends to feed 40 liquid refrigerant into the evaporator II when the refrigerant pressure therein falls below a predetermined limit. However, this valve 22 is also controlled by a thermostatic bulb 23 placed adjacent the outlet of evaporator, and this bulb 23 45 throttles the valve 22 whenever liquid refrigerant 55 The arrangement is such that the'speed of the decrease when that temperature decreases.
compressor i1 is automatically increased when the temperature created by the evaporator I increases, and the speed of the compressor tends to This is accomplished by providing a temperature responsive means 26, responsive either to dry bulb temperatures or wet bulb temperatures, or both, inthe compartment ill, which automatically varies the setting of the speed responsive device 25 to accomplish this purpose. Thus the bulb 26 is connected by a pipe 21 with an expansion bellows 28 adjacent the transmission 25. The bellows 28, when expanded, forces the cone 29, against levers 30 which are pivoted in 3 This in turn causes the levers 33 to forcethe flange 32 toward the flange 33 and thus tends to force the belt 34 radially outward from the shaft 35 of motor 24. This increases the effective diameter of the pulley. When this occurs, the belt 34 forces the flanges 36 and 31 of the pulley 38 on the compressor i'l outwardly against the spring 38a and reduces the effective diameter of the pulley on the compressor shaft. This increases the speed of the compressor as the temperature in the compartment 0 rises. When the temperature in the compartment l0 decreases the converse operation occurs and the speed of the compressor is accordingly decreased.
The variable speed transmission 25 may take any desired form, but as abovedescribed, the form shown is now preferred. The cone 29 is slidably keyed at 39 so that the same may slide axially on the-shaft 35, but must rotate therewith. The fulcrums 3| are mounted on the sleeve 40 which is flxed on the shaft 35 through the hub 4| of flange 33 which is likewise fixed on shaft 35 through the medium of a key 42 and a set screw 43. The flange 32 is slidably mounted on the hub 4| so that the same may move axially; but is keyed against relative rotation by the pins 44. Also the flange 32 is pressed against the levers 30 by the spring 32a. The levers 30 are provided with a flexible band 45 which tends to contract the right hand ends of the levers against the cone 29. A lever 48 is fulcrumed at 41 with one end in an engagement with the bellows 28 and is provided at the other end with an anti-friction roller 48 incontact with the cone 29.
If desired, the motor 24, and consequently the compressor I1, is caused to start and stop automatically in response to temperature conditions in the compartment ID. This is accomplished by providing a thermostatic switch 50 with its temperature response element 5| placed in com- 'created by the evaporator ii. This switch may be responsive to dry bulb, or wet bulb temperatures, or both'fi. The switch causes the motor 24 to'start when the temperature in the compart ment i0 'rises ove a predetermined limit, and causes the moto to stop when temperature falls below a predetermined limit. Both of these limits, whether they are identical or different, are preferably near thelower range of comfort temperature, so that the compressor starts to operate when the temperature rises sufficiently to require air conditioning and so that the compressor, stops when the temperature falls near the lower comfort range when no refrigeration is required.
The various parts of the apparatus are so calibrated that the refrigerant temperatures of the evaporator II are maintained sumciently low to create comfort conditions in the compartment to, but the refrigerant temperatures are maintained sufliciently high to prevent thefreezing of moisture from the. stream of air passing through compartment I4 on the evaporator. The temperature may be sufllciently low to condense moisturefrom the air, but not to freeze it. Any moisture thus condensed may accumulate in being drained from the pan 52 placed below the evaporator ll.
In operation, when the temperature in the compartment rises to the-point where refrigeration is required, the switch 50 causes the. motor 24 to operate. The temperature responsive means 28 then actuates the lever 16 to the proper position' to insure the proper speed of rotation of the compressor shaft. The means 26 may be manually set so that the apparatus tends to maintain higher or lower temperatures. Thus the nuts 53 and 54 may be tumed'against the fixed stop 55 to vary the tension on the spring evaporator, an electric motor, means controlling the operation of said motor in accordance with temperature conditions, a variable speed mechanical connection between said motor and unit and means for controlling said variable speed connection in accordance with air conditions in said compartment.
2. An air conditioning apparatus comprising a compartment to be cooled, an evaporator for cooling air for said compartment, av refrigerant .f'lique'fying unit operatively connected to said evaporator, an electric motor, means for starting and stopping said motor automatically in accordance with refrigeration demands, a var-v iable speed mechanical connection between said motor and unit and means for controlling said compartment to be cooled, an evaporator for cooling air for said compartment, a refrigerant liquefying unit including a compressor and condenser operatively connected to said evaporator,
an electric motor, a thermostatic switch controlling the operation of said motor, a variable speed mechanical connection between said motor and compressor and means for controlling said variable speed connection in accordance with the I cooling effect of said evaporator on air discharged into said compartment. 4. Anair conditioning apparatus comprising a compartment to be cooled, an evaporator for cooling air for said compartment, a refrigerant liquefying unit including a compressor and condenser operatively connected to said evaporator, an electric motor, an element responsive to conditions in said compartment controlling the operation of said motor, a variable speed mechanical connection between said motor and unit and means for controlling said variable speed connection in accordance with the cooling effect of said evaporator on air in said-compartment.
5.-An air conditioning apparatus comprising a compartment to be cooled, an evaporator for cooling air for said compartment, a refrigerant liquefying unit operatively connected to said evaporator, a constant speed electric motor, means for automatically starting said motor in accordance with refrigeration demands, a variable speed mechanical connection'between said, motor and unit and means for controlling said variable speed connection in accordance with the cooling eflectofi said evaporator on air in said compartment.
6. An air conditioning apparatus comprising an evaporator, compressor and condenser in refrigerant flow relationship, a constant speed electric motor, a mechanical transmission between said motor and compressor, means controlling the operation, of said motor in accordance with refrlgeration demands and means automatically responsive to temperature conditions created by said evaporator to, increase-the speed of said compressor when the temperature increases and to decreaselthespeed of said compressor when the. temperature decreases, said means including a mechanical variable ratio drive and a thermostat actuating said drive to vary the driving ratio, said thermostat being independent of evaporator temperatures.
'7. An air conditioning apparatus comprising an evaporator, compressor and condenser in refrigerant flow relationship, a fan for blowing air over said evaporator, a motor driving said fan, a constant speed electric compressor motor, a mechanical transmission between said compressor motor and compressor, and means automatically responsive \to air temperature conditions ore--55 ated by said evaporator to adjust said transmistric motor, a mechanical transmission between ,7
said motor and compressor, means automatically responsive to air temperature conditions created by said evaporator to adjust said transmission to increase the speed oi said compressor when the air temperature increases and to decrease the speed of said compressor when the air tempera- 7o ture decreases, and means responsive to temperature conditions created by said evaporator for starting and stopping said motor.
9. An air conditioning-apparatus comprising an evaporator, compressor and condenser in re- 75..
frigerant flow relationship, a fan for blowing air over said evaporator, a constant speed electric motor, a mechanical transmission between said motor and compressor, means automatically responsive to air temperature conditions created by said evaporator to adjust said transmission to increase the spied of said compressor when the air temperature increases and to decrease the speed of said compressor when the air temperature decreases and means responsive to temperature conditions created by said evaporator for starting and stopping said motor.
10. An air cooling apparatus comprising a compartment to be cooled, an evaporator cooling air for said compartment, a compressor and condenser connected to-said evaporator in refrigerant flow relationship, an electric motor, a variable ratio drive between said motor and compressor, and means for adjusting said drive in accordance with air conditions in said compartment.
11. An air cooling apparatus comprising a compartment to be cooled, an evaporator cooling air for said compartment, a compressor and condenser connected to said evaporator in refrigerant flow relationship, an electric motor, a variable ratio drive between said motor and compressor, and means for adjusting said drive in accordance with air conditions in said compartment, said drive and adjusting means comprising a driven compressor V-pulley, spring means urging the sides of said V-pulley together, a motor driving V-pulley, a belt between said pulleys, and thermostatic means varying the distance between the sides of said driving V-pulley.
12. An air conditioning apparatus comprising a compartment to be cooled, an evaporator for, cooling air Ior said compartment, a refrigerant liquei'ying unit including a compressor and condenser operatively connected to said evaporator, an electric motor, a thermostatic switch controlling the operation of said motor, a variable speed mechanical connection between said motor and compressor, and means for controlling said variable speed connection in accordance with temperature conditions of air at a point within said compartment remote from said evaporator.
CHARLES F. HENNEY.
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US721512A US2130995A (en) | 1934-04-20 | 1934-04-20 | Refrigerating apparatus |
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US721512A US2130995A (en) | 1934-04-20 | 1934-04-20 | Refrigerating apparatus |
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Cited By (15)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2521457A (en) * | 1944-06-05 | 1950-09-05 | Internat Powermatic Corp | Automatic variable ratio transmission |
US2660069A (en) * | 1950-02-24 | 1953-11-24 | Cockshutt Farm Equipment Ltd | Variable speed transmission |
US2787129A (en) * | 1954-05-19 | 1957-04-02 | Gen Motors Corp | Automobile refrigerating apparatus |
US2807148A (en) * | 1954-11-29 | 1957-09-24 | Gen Motors Corp | Refrigerating apparatus |
US2851865A (en) * | 1954-11-29 | 1958-09-16 | Gen Motors Corp | Vehicle refrigerating apparatus |
US2866528A (en) * | 1954-03-26 | 1958-12-30 | Gen Motors Corp | Clutch for refrigerating apparatus |
US3048022A (en) * | 1959-07-15 | 1962-08-07 | Thompson Ramo Wooldridge Inc | Compressor control in automotive air conditioning system |
US3369417A (en) * | 1965-02-23 | 1968-02-20 | Robertshaw Controls Co | Pneumatic speed control means and method |
US4357806A (en) * | 1980-10-10 | 1982-11-09 | Dana Corporation | Controller for variable air volume cooling system |
US4454236A (en) * | 1981-07-07 | 1984-06-12 | Dayco Corporation | Belt tensioner and method of making same |
US4787214A (en) * | 1987-11-23 | 1988-11-29 | Thermo King Corporation | Transport refrigeration system |
US4800730A (en) * | 1984-07-16 | 1989-01-31 | Suetrak Transportkaelte Gmbh | Arrangement for influencing the speed of a compressor of a refrigerating system |
US5048302A (en) * | 1990-02-09 | 1991-09-17 | Hudson Associates, Inc. | Refrigerant system having controlled variable speed drive for compressor |
US5341868A (en) * | 1992-02-07 | 1994-08-30 | Zexel Corporation | Operating device for air-conditioner |
US6634939B2 (en) * | 2001-08-31 | 2003-10-21 | Thomas W. Johnson | Ventilation system and method |
-
1934
- 1934-04-20 US US721512A patent/US2130995A/en not_active Expired - Lifetime
Cited By (15)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2521457A (en) * | 1944-06-05 | 1950-09-05 | Internat Powermatic Corp | Automatic variable ratio transmission |
US2660069A (en) * | 1950-02-24 | 1953-11-24 | Cockshutt Farm Equipment Ltd | Variable speed transmission |
US2866528A (en) * | 1954-03-26 | 1958-12-30 | Gen Motors Corp | Clutch for refrigerating apparatus |
US2787129A (en) * | 1954-05-19 | 1957-04-02 | Gen Motors Corp | Automobile refrigerating apparatus |
US2807148A (en) * | 1954-11-29 | 1957-09-24 | Gen Motors Corp | Refrigerating apparatus |
US2851865A (en) * | 1954-11-29 | 1958-09-16 | Gen Motors Corp | Vehicle refrigerating apparatus |
US3048022A (en) * | 1959-07-15 | 1962-08-07 | Thompson Ramo Wooldridge Inc | Compressor control in automotive air conditioning system |
US3369417A (en) * | 1965-02-23 | 1968-02-20 | Robertshaw Controls Co | Pneumatic speed control means and method |
US4357806A (en) * | 1980-10-10 | 1982-11-09 | Dana Corporation | Controller for variable air volume cooling system |
US4454236A (en) * | 1981-07-07 | 1984-06-12 | Dayco Corporation | Belt tensioner and method of making same |
US4800730A (en) * | 1984-07-16 | 1989-01-31 | Suetrak Transportkaelte Gmbh | Arrangement for influencing the speed of a compressor of a refrigerating system |
US4787214A (en) * | 1987-11-23 | 1988-11-29 | Thermo King Corporation | Transport refrigeration system |
US5048302A (en) * | 1990-02-09 | 1991-09-17 | Hudson Associates, Inc. | Refrigerant system having controlled variable speed drive for compressor |
US5341868A (en) * | 1992-02-07 | 1994-08-30 | Zexel Corporation | Operating device for air-conditioner |
US6634939B2 (en) * | 2001-08-31 | 2003-10-21 | Thomas W. Johnson | Ventilation system and method |
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