DE1451002C - Deicing control device - Google Patents

Description

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The present invention relates to an additional advantage that in a mechanical de-icing control device for automatic de-jamming of the thermal element of the de-icing cycle of the heat exchanger in cooling systems, the defrosting process is not continued indefinitely, but instead from one to the is interrupted for a certain period of time, the electrical circuit is connected 5 As a result, even if a faulty toggle switch occurs, on the one hand a timer provided with a function of the thermal element, and on the other hand, a more or less satisfactory cam plate, and the other- related operation of the cooling system can be maintained on the temperature of heat generation,
exchanger's appealing thermal link can be actuated. The invention is based on one

De-icing control devices for the io exemplary embodiment have already been explained and described in more detail.

automatic defrosting of the heat exchanger at ben, reference being made to the drawings

Cooling systems known (U.S. Patent 2,674,665) is. It shows

in which a bistable toggle switch is provided; FIG. 1 is a schematic representation of a mi;

is that with the help of a timer in its de-icing of the de-icing control device according to the invention position is switched and with the help of a cooling system provided on the 15,

Temperature of the heat exchanger responsive F i g. 2 is a top view of the de-icing control

Thermal link back to its normal working device according to the invention,

position is brought. Since the de-icing control input F i g. 3 is a side view of the de-icing control

direction usually only once during the night setup along line 3-3 of FIG. 2,
is to be actuated, the cam of the timer rotates so F i g. 4 to 6 along enlarged sectional views

encoder extremely slowly. Hence it is necessary to line 4-4 of FIG. 3 with representation of the

dig, on the cam of the timer a different working position of the de-icing control

To provide a snap mechanism in order to

to achieve setting actuation of the toggle switch. F i g. 7 to 9 enlarged partial sectional views ent- It has been found, however, that this is on the 25 long of the line 7-7, 8-8 and 9-9 of FIG. 4,
Cam plate arranged snap mechanism Fig. 10 an even further enlarged partial section of the timer works imprecisely, so that the time view of the elements shown in Fig. 9,
point at which the de-icing cycle was triggered in time In F i g. 1 is a reversible heat pump is relatively poorly defined. Furthermore, several individual parts 30 device according to the invention are shown for a system which has a deicing control device-like snap mechanism. The heat pump required, which on the one hand increases the manufacturing costs of the system includes a conventional compressor-condenser-defrosting control device, on the other hand the sator-evaporator circuit with a Motorkompressoi impair the operational safety of the same. 10, an electromagnetically operated reversing

Accordingly, it is an object of the present invention, valve 12, an indoor heat exchanger 18, a

a de-icing control device for the automatic 35 external heat exchanger 19 and a capillary 20,

De-icing of the heat exchanger in cooling systems which reduce the flow between the heat ex-

to create that does not reduce these disadvantages mentioned above.

The motor compressor 10 is guaranteed by electrical lines 21, 22, which are very precisely defined in terms of time and not susceptible to interference, and a suitable thermostat triggering of the defrosting cycle and subsequent switches 23 on power lines L 1 and L 2 at the end of the same. . closed. The thermostat switch is in the from

According to the invention this is achieved in that the interior heat exchanger 18 to be temperature-controlled space of the toggle switch is monostable and is located in its stable. It periodically switches the motor compressor position the defrosting current sensor 10 off and on, as is necessary, to complete a cycle, while it is set by the timer 45 in the temperature-controlled room as well as by the thermocouple in its unstable position keep upright. The reversing valve 12 is held or returned to the same, in is seated an electromagnet 12 a, which is opened over soft conductors 24, 25 on power lines L1 and circuit suitable for the defrosting process. L 2 is connected and a de-icing control

Due to the fact that the toggle switch 50 tion 26 is controlled, which the present invention

is monostable and embodied during normal operation finding and subsequently in detail

is described by the cam of the timer in its.

unstable position is held, results automatically, the reversing valve 12 is by excitation or that with the slow rotation of the cam plate de-excitation of the same electromagnet 12a because the cam plate scanning element to a 55 actuated that it the system at a certain point in time in the recess the state of the curve, which can occur in relation to the inner pane, which triggers the heat exchanger 18 to be temperature-controlled, results in the room icing cycle. As this collapse provides cooling or heating.
'Sensing element for a very short time - Sol! So this room is heated, so the room takes place, no special snap 60 internal heat exchanger 18 as a condenser, while mechanism for triggering the de-icing cycle of the external heat exchanger 19 as a Verdamplus is necessary. As a result, there is an essential function. The coolant flows from the discharge of the simpler design of the de-icing control side of the motor compressor 10 through the pipe 28 device, which is advantageous with regard to the reversing valve 12, the pipe 29, and the insusceptibility of the same to internal malfunctions. 65 heat exchanger 18, the capillary 20, which is used as a

Since the silencers that trigger the defrosting cycle, the external heat exchanger 19, the

Savings of necessity can only be achieved through a pipe 31, the reversing valve 12 and the pipe 32

Extending part of the cam disc results again in the inlet side of the motor compressor. There:

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hot compressed gas from the motor compressor also has at its free end a downward 10 is condensed in the heat exchanger 18 and bent hook 55 a. A toggle spring gives heat to the temperature to be controlled 58 extends between the hook 55 a and space. The condensed coolant then passes to a U-shaped knee joint 59, which is exchanged through the capillary 20 for expansion into the heat 5 a central opening of the switch arm 51, in which the coolant is arranged in heat and with this arm close to the free from the This end of the same is in rotatable engagement via the evaporator windings 19 α. The be exchanger takes in circulating air. This activating arm 55 is under the influence of a spring, the evaporator coils 19 α of the heat 58, which strives to swivel it clockwise around exchanger 19 considerably - that is, usually on io projections 57 around in a position, temperatures below freezing point from which the movable contact 50 into the water-cooled. Temporarily, for example during FIG. 5 plant shown on the fixed contact 49 early morning hours in which the humidity is brought so a circuit between the is relatively high, there is thus the tendency that terminals 45 and 46 to trigger a Entauf the evaporation windings 19 α ice is deposited. 15 icing cycle to complete. If the Be-This isolates the evaporation windings 19 a and activation arm 55 counterclockwise to reduce their heat exchange efficiency. Projections 57 by means of those described below

The defrosting cycle is pivoted by energizing the agent, so the knee joint mechanism electromagnet 12.α with the aid of the controller 26 a triggers the contact 50 from the stationary contact 49. The reversing valve 12 thereby returns the 20 to the fixed contact 52 in the position shown in FIG. 6 ge coolant flow to the heat exchangers 18 and showed position reversing to interrupt the defrosting period 19 to allow hot to interrupt or terminate immediately from the grain,
The cooling gas coming from the pressor 10 flows directly into the heat exchanger 19 and the same switch 42 can be heated through a substantial differential for reasons that will emerge below. As soon as the temperature of the 25 see the positions of the actuating arm 55 ge heat exchanger 19 indicates a predetermined above, in which the contact 50 has reached between the freezing point temperature, fixed contacts is moved. Others causes the controller 26 to de-energize the Eiek- known embodiments of switches with a tromagnet 12 a, so that normal operation is resumed with a considerable differential between the active parts. The de-icing control device 30 lungs of an actuating arm can be used in the embodiment according to the invention is designed in such a way that the invention is used. The switch that the solenoid valve 12 α in timed Ab- 42 was described as a preferred example,
stands and is only actuated when the movement of the actuating arm 55 for loading evaporator windings 19 α on the freezing point actuation of the switch 42 is partly as a reaction or below the same. 35 to predetermined temperature conditions of the

The defrosting control device 26 has a steamer effects as it depends on the temperature

suitable sheet metal frame 41 with side walls 41 α temperature responsive means are shown, and

and 41 b, end walls 41 c and 41 d and one in part in response to the passage of time, as seen from

Top wall 41 e. An electrical timer is provided on the frame 41, as described below.

Snap switch 42 mounted, which is given an insulating base 40. The one that responds to the temperature

plate 43 has. This is by means of noses 43 a, device includes a temperature sensing element such as

which protrude from her, in the side walls 41 α the piston 36, the one in the outer snake 19 α

and 41 b attached, which corresponding openings heat pump system is arranged so that he

have into which the noses protrude. The temperature switch of the exiting queue

42 has terminals 44, 45 and 46. The terminals 45 feel air. The temperature sensing piston 36

45 and 46 form part of a control circuit for is through a suitable capillary tube 37 with the base of the reversing valve electromagnet 12 a. As shown in 73 of an expandable force element or bellows 74 F i g. 4 and 7 can be seen, forms the inner end of the connected. The base 73 of the bellows 74 is attached to a clamp member 45, a conductor bar 47 which is mounted on the cup member 75, which is located by means of an insulating base plate part 43 and has a threaded hole 50 screws 76 on the end wall 41c of the frame 41. This takes a screw 48 in itself, has attached flange 75 α. The bellows protrudes dawelche a normally fixed, but at through a window in the frame. The bellows 74 carries adjustable contact 49. A movable double seated an axially movable bellows pin 76 for the pelkontakt 50 is carried by one end of a flexible transmission of the movement to a now be-Schaltarmes 51 so that it is in a snap 55 written bellows lever 80. The piston 36, the Kapilbewegung between the stationary contact 49 lar tube 37 and the bellows 74 are connected to a suitable, and another stationary contact 52, a medium that expands under the influence of heat, is bar. The latter contact is preferably filled with a vaporizable medium at the inner end, the terminal 44 connected, which has the shape of a so that the position of the bellows pin 76 in each case in Uber bridge 44 a. The other end of the switch 60 in accordance with the coldest part of the medium arm 51 is attached to the inner end 46 a of the clamp 46 containing system in a manner that is regulated, and the arm is in the form of a snap which is used by those skilled in the art the field to which movement by means of movement of the invention relates is well understood,
pivotable actuating arm 55 actuatable bellows lever 80, which preferably moves as a stamped sheet metal toggle lever device. The actuating arm 55 65 is formed part and a central surface part has laterally spaced support parts 56, which on 80 a and spaced parallel support blade-like projections 57 at the inner end parts 80 b is at one end between the

46 a of the terminal 46 are pivotably mounted. He sides walls 41a and 41b of means .Rahmens

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a pivot pin 81 is pivotably mounted, which furthermore parallel side parts at a distance from one another extend through aligned openings in the bearing parts 95 b, which extends aligned openings 80 b at one end. The bellows lever 80 has a tongue that receives the pivot pin 81. 80 c, which is bent so that it is with one edge The free end 80 ti of the bellows lever 80 is above the knife-edge-like with the bellows pin 76 in the single 5 surface part 95 a is near the movable end of the handle. A tension spring 83 strives to the bellows lever lever 95, which is provided with a tongue 95 c . The 80 in the drawing counterclockwise to tongue 95 c will rotate from the hook-shaped end 97 α one and holds it in follow-up contact on the bellows pin. Secondary load spring 97 is comprised by an adjustment die best shown in FIG. 6 recognizable spring 83 engages screw 99 and a nut 99 α is connected to a cam with a hook-like end 83 α in opening scanning lever 98. The lever 98 comprises openings in the flat part 80 α of the bellows lever 80 a. Tongues 98 a, which extend through a slot 41 / in the end turns of the other end 83 b of the side wall 41 b and so a pivot spring 83 are in engagement with a nut 85 in connection with this form. The lever 98 comprises the thread of which an adjusting screw 86 is inserted. This also has a projection 98 b at the other end of the extends through an opening in the top wall 15 of the lever on the cam circumferential surface of a

41 e of the tax framework. The head of the screw 86 cam 100 mounts. The corners of the lever 98 which is applied with a screwdriver slot 87 for rotating on the wall 41 &, are preferably provided with the screw 86 for the purpose of adjusting the tension pivot points 98 c to the friction on a the spring 83 and thus the load of the bellows 74 to reduce the minimum level. One of the tongues 98 a is provided. A block 90 of insulating material is attached to 20 for the purpose of holding the tongues in the slot 41 / with a screw 91 which is provided in an opening of one bent end 98 d .

flat part 80 α of the bellows lever 80 screwed. The cam 100 is at the inner end of a Einist. The isolating block 90 can be attached to the switch actuating shaft 101, which is rotatably engaged in the sidebar 55. wall 41 α of the frame is mounted and one

If the temperature at the piston 36 drops below a 25 screwdriver slot 101 α for adjusting the

predetermined temperature, this leads to a loading wave and the cam. A twist of the

eighth contraction of the bellows 74 and there cam 100 in a clockwise direction, as in FIG. 2 and 4

visible with a rotation of the bellows lever 80 and that of the drawings acts to that effect on the

Isolation block 90 counterclockwise to the cam follower 98 that the spring 97 is elongated Pivot pin 81 under the influence of the spring 83. 30 and the resistance of the lever 95 against his

Such movement tends to cause the block 90 clockwise rotation about the pivot pin

away from actuator arm 55 as it grows in 81. The rotation of the lever 95 against the

F i g. 4 is shown. Conversely, a clockwise increase about pivot pin 81 is performed

the temperature at the piston 36 limits a stop 102 to an expansion, which from the side wall of the bellows 74 and a rotation of the bellows lever 35 41 & protrudes inward. The end part 8OiZ of the BaIg-

80 and the insulating block 90 clockwise to the hebeis 80 can with the flat part 95 b of the loading

Actuating arm 55 out, as shown in FIG. 5 is shown. load lever 95 come into engagement to the latter

Move the adjustment of screw 87 and spring 83 away from stop 102 when the temperature

is such that when the piston 36 cools to approximately temperature the outer coil 19 α during the development

0 ° C, the bellows 74 contracts so far and the icing period exceeds the normal operating temperature for 40

the bellows arm 80 and the insulating block 90 is controlled in one ratur. The result of this

such extent counterclockwise moves load lever 95 and its spring 97 on the bellows

be that the switch actuating arm 55 an increased load exerted 74 leads to the fact that the

jump of the movable contact 50 towards the end of the defrosting period on the queue

causes fixed contact 49 out, whereby the 45 19 α a relatively high temperature is required.

Circuit between terminals 45 and 46 for this ensures that the correct

Triggering a defrosting period is closed, all ice is defrosted. This termination temperature

provided that, as described below, a temperature can - as described above - be

timed event occurs. During the hung of the cam 100 for the purpose of setting the clamping

De-icing period, the snake 19 α for the purpose of 50 voltage of the spring 97 will be set arbitrarily.

Liberation of the same from the ice warmed up, and with increasing temperature, thus triggering a defrosting period only

gender temperature of the snake 19 α and the KoI- is possible if at the same time a predetermined one

bens 36 move the bellows arm 80 and the insulating low temperature prevails on the piston 36 and

block 90 clockwise on movement of a predetermined time is the device

Switch 42 in an open position. 55 26 with a timer motor driven

To a complete de-icing of the snake 19 α surrounded cam 110 provided, which the location of a

To ensure the defrosting period, only spring-loaded locking lever 111 controls. This is

then terminates when a noticeably above that between the cam or the cam 110

normal operating temperature of the outer coil and an insulating sleeve 112 arranged, which last

Low temperature is reached before the switch 60 tere to an upwardly bent arm portion 55 b

42 is brought into an open position. To this the switch operating lever 55 is seated. The purpose of the locking lever is an additional bellows loading device 111 is formed from a sheet metal strip and has a secondary load lever 95 around one end of an eye 111 a, in which a bearing engages. The load lever 95 is appropriately made of sheet metal pin 113 sits, with the help of which the lever 111 is pressed; it has a central flat part 95 α 65 pivotable between the side walls 41 α and 41 & with an opening (Fig. 5) through which one of the control frame sits. At the other end is the part of the bellows lever and the block 90 and levers 111 with a cam follower 111 & screw 91 extend. The load lever 95 has see which on the peripheral edge or cam

I 451 002

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On the surface of the cam or cam 110, the block 90 comes into engagement with the arm 55

rides up. A leaf spring 114 holds the lever 111 in and pivots it counterclockwise until

by swiveling it clockwise, the desired maximum temperature of the snake

tet around the bearing pin 113, in constant contact with the 19 α is reached and - as in F i g. 6 shown - the

Cam disk 110. One end of the spring 114 is operated at 5 switch 42 in the opening sense, which

For example, attached to the lever 111 by rivets 130. the defrosting period ends. Then he returns

The other end of the spring engages an evaporator opening to return to its normal operating temperature

115 of the control frame wall 41e . One back. In this state, the bellows changes

Screw 116 extends through an opening in an amount which is less than that

Lever 111 and is in an aligned threaded hole in the amount that is required to move the block 90 from

the leaf spring 114 is screwed in. To retract the screw 116 arm 55 into a position which is a

can be allowed with the insulating sleeve 112 on the actuation actuation of the switch, even if a

arm 55 come into engagement and is adjustable to the cam recesses 119 a, 119 b below

the functional distance between the locking lever 111 the cam disc scanning part 111 b passes,

and to be able to adjust the actuating arm precisely. 15 If there is an icing on the queue 19 a

The cam 110 is contracted clockwise (in the view of temperature and the bellows 74 continuing to drawings) by a suitable one so that the lever 80 and the timer motor, such as an electrical syn-block 90, are in their in FIG . 4 layers shown gelanchronmotor 120, rotated, which is attached to the side wall, so the alignment of one of the ver-41 b of the control frame is attached. As from 20 depressions 119 a or 119 b with the Nockenabtast-F i g. 9 and 10 shows the cam or part 111 & for triggering a defrosting period. the cam 110 from a remote shaft 121 It can be seen that the control device 26 for the worn which ensures a tapered end portion 122 up triggering of a de-icing period when adduced, which is mounted in the side wall b 41st The specific icing temperature and time condition cam is also present by waving a shoulder 25 and that the Ent-124 is attached to a shoulder 123 in abutment. A freezing period as a function of or as a re-spur gear 126 is ended on the shaft 121 between an action on a predetermined high temperature shoulder 127 of the shaft and a disk 128.

solidifies. The latter is in clamping engagement with the control device 26 according to the invention

Spur gear 126 by waving a shoulder 30 ensures a positive termination of the de-icing

129 of the wave. The gear 126 meshes with a period even in the event of an error on the

Drive pinion 131 of the motor 120, which the shaft temperature responsive device, z. B. if

121 and thus also the cam 110 with a common leakage point the medium from this device

rotates at a suitable speed, such as stepping around and collapsing the bellows 74,

rotation per hour. 35 So the de-icing period is not within one

The cam 110 is located in the FIG. 4 predetermined period of time by the temperature

position shown, wherein the Nockenabtastteil 111 b temperature responsive device has been terminated,

of the lever 111 is on the high cam - so the lever 111 is counterclockwise

circumferential surface 117 is located α. It is pivoted by the cam 110 when the cam

the lever 111 in a position in which it has a loading 40 scanning part 111 b of the relatively low cam

Movement of the switch actuating arm 55 in the clock surface 118 α or 118 b to a higher surface 117 b

clockwise for the purpose of triggering a de-icing or 117 a rises. After that the introduction

period prevented even if only on the piston 36 and termination of the defrosting period

an icing temperature prevails and the bellows 47 effects on a time basis.

has contracted so far that the insulating 45 Under certain operating conditions, e.g. B. at

block 90 from the actuating arm sufficient distance of high humidity, it is desirable to

in order to allow the switch to be operated in quicker succession during the closing period.

to allow the senses. than when operating in drier conditions.

If the cam or the cam is rotated accordingly, the control device 26 sees the cam scanning part 111 & of the 5 ° also means for alternating bridging or lever 111 on the surface 118a and then releases one of the depressions 119 & in the circumference the recess 119.α a; as a result, the cam 110 can advance. As a result, the pre-actuating arm 55 can be moved into its position according to FIG. 5 direction 26 can optionally be set so that they pivot, whereby the contact 50 comes into contact with the contact per revolution of the cam disk either one cycle 49 and initiates a de-icing 55 or two de-icing cycles. To this cycle triggers. The further rotation of the cam 110 purpose is a mask 135 (Figs. 4, 9 and 10) showing the cam scanning part as seen on the surface 118α. This has a ring part 135 a, which rotates back. The simultaneous rotation of the bar on the shaft 121 between a shoulder 136 actuating arm 55 counterclockwise is sufficient for the same and a disk spring washer 137, but is not sufficient for the above-mentioned differential 60 to be. The outer edge of the plate spring 137 rests against the gear 126 between the reversed positions of the switch. The spring washer 137 is used to overcome. The defrosting period is thus continued as a clutch, which sets the mask 135 by friction. revolves with the cam 110. She allows it

If now the temperature of the snake 19 α and, however, the mask using stronger

of the piston 36 increases, the lever 80 is clocked 65 forces against the cam 110 by the in

pivoted clockwise, and the end part 80 d des- E% ® F i g. 4 in the fully extended position shown

same takes the secondary load lever 95 α - as in dashed line position 135 'to rotate, in wel-

F i g. 5 shown - with. During this movement, the end of the mask tends to cross the recess 119 b

covers and thus prevents the Nockenabtastteil 111 b of the lever 111 from falling in the corresponding rotational position of the cam 110 in this recess.

The rotation of the mask 135 relative to the cam disk 110 is effected with the aid of a bushing 140 which surrounds the shaft 121 and has a recess 141. A tongue 105 b protrudes into this recess or this recess from the mask ring 135 α through an arcuate opening 142 in the cam disk 110. The bushing 140 protrudes through the frame side wall 41 (FIG. 3 and is mounted in it. It can be seen that a rotation of the bushing 140 about the shaft 121 can cause the mask 135 to rotate through an angle of approximately 90 °, which is intended to bridge and clear the recess 119 through the arcuate slot 142 in the cam 110. The cam 110 and the shaft 120 are through the engagement of the gear 126 with the pinion 131 is prevented from rotating when the mask 135 is rotated. The pinion 131 is driven by the motor via a transmission gear, which reduces the speed to such an extent that it cannot be taken along. The socket 140 is provided with markings, For example, as shown in Fig. 1, with numbers 1 and 2, which with a screwdriver slot 21a in the shaft 121 for the purpose of setting one of the two possibilities, an o of setting two defrosting periods per rotational speed of the cam disk 110 can be brought into agreement.

Claims (5)

Patent claims: 1. De-icing control device for automatic de-icing of the heat exchanger Cooling systems, consisting of an electrical circuit that causes the defrosting process connected toggle switch, on the one hand by a cam provided with a Timer and on the other hand a responsive to the temperature of the heat exchanger Thermal link can be actuated, characterized in that the toggle switch (42) is monostable and in its stable position the the defrosting circuit closes while it is both from the timer (120, 131, 126, 110) as well as by the thermal link (36, 37, 74) held in its unstable position or is returned to the same in which the circuit causing the defrosting process is opened is. 2. Deicing control device according to claim 1, characterized in that the Thermal member (36, 37, 74) with its bellows (74) on two around a common axis (81) pivotable, separately sprung and adjustable with regard to the applied spring force Lever (80, 95) acts, one of the two levers (95) from a certain angular position is locked by a stop (102). 3. De-icing control device according to claim 1, characterized in that the cam of the timer (120, 131, 126, 110) has recesses (118α-119α, U8b-119b) along which a cam scanning part ( 42) connected to the toggle switch (42) UIb) slides. 4. De-icing control device according to claim 3, characterized in that the cam disc (110) has two recess areas (118 a, 118 b, 119 a, 119 b) of different depths, the incidence of the Nockenabtastteils (HIb) from the upper to the lower area Actuation of the toggle switch (46) to trigger the defrosting cycle causes an opposite actuation only when the cam scanning part (HIb) is raised again from the upper area (118 a, 118 b) to the circumferential area (117 a, IVJb) of the cam disk (110) the toggle switch (46) to terminate the defrost cycle. 5. De-icing control device according to claim 3 or 4, characterized in that a along the circumference of the cam (40) displaceable mask (135) is provided, with which one of the deep recess areas (119 b) of the cam (110) can be covered. For this purpose 2 sheets of drawings