CN102589207B - Refrigeration system and thermostatic expansion valve thereof - Google Patents

Refrigeration system and thermostatic expansion valve thereof Download PDF

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Publication number
CN102589207B
CN102589207B CN201110026552.6A CN201110026552A CN102589207B CN 102589207 B CN102589207 B CN 102589207B CN 201110026552 A CN201110026552 A CN 201110026552A CN 102589207 B CN102589207 B CN 102589207B
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valve
heating power
expansion valve
power expansion
valve body
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CN102589207A (en
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刘长青
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Zhejiang Sanhua Commercial Refrigeration Co ltd
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Zhejiang Sanhua Co Ltd
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Abstract

The invention discloses a thermostatic expansion valve comprising a valve body, wherein the valve body is provided with a gas tank at the upper end, and an inner cavity of the gas tank is divided by a membrane into an upper cavity and a lower cavity; a valve core component and a valve port matched with the valve core component are arranged in the inner cavity of the valve body, and the lower end part of the valve core component is arranged in a balancing cavity of the valve body. The thermostatic expansion valve is characterized in that a sealing component is further arranged between the balancing cavity and the inner cavity of the valve body, a through hole is further arranged on the valve body, the balancing cavity and the inner cavity of the valve body are isolated and sealed by the sealing component, and the balancing cavity is communicated with the lower cavity by the through hole. According to the structure design of the thermostatic expansion, the system pressure difference applied on the valve core component is reduced so as to improve the adjusting precision of the valve core component. Furthermore, the invention further discloses a heat exchange device comprising the thermostatic expansion valve.

Description

Refrigeration system and heating power expansion valve thereof
Technical field
The present invention relates to refrigerant fluid control component technical field, particularly a kind of heating power expansion valve.In addition, the invention still further relates to a kind of refrigeration system comprising this heating power expansion valve.
Background technology
Heating power expansion valve is the vitals of composition refrigeration system, is another basic element of character removed in refrigeration system four basic elements of character outside evaporimeter, compressor and condenser.The Main Function of heating power expansion valve carrys out the aperture size of control valve by the degree of superheat of evaporator outlet end or compressor suction side in induction refrigeration system, thus realize the object of the adjustment of system cold medium flux and reducing pressure by regulating flow.
Please refer to Fig. 1, Fig. 1 is the structural representation of a kind of typical heating power expansion valve in prior art.
This heating power expansion valve comprises valve body 1 ', and the upper end of valve body 1 ' is connected with the gas tank comprising the gentle case lid 2 ' 5 of gas tank seat 2 ' 4, and the inner chamber of this gas tank is divided into epicoele 2 ' 2 and cavity of resorption 2 ' 3 by diaphragm 2 ' 1; As shown in Figure 1, epicoele 2 ' 2 is by being filled with refrigerant and being connected with temperature-sensitive bag 4 ' 2 by capillary 4 ' 1, and temperature-sensitive bag 4 ' 2 for experiencing the degree of superheat of the refrigerant of evaporator outlet end or suction port of compressor end, and produces a temperature, pressure P in epicoele b; Meanwhile, cavity of resorption 2 ' 3 is communicated with described evaporator outlet end by balance pipe (not shown), thus produces an evaporating pressure P in cavity of resorption 2 ' 3 o.
In addition, as shown in Figure 1, be formed with valve port 1 ' 1 in the inner chamber of valve body 1 ', this valve port 1 ' 1 is combined with spool 3 ' 1, and the upper end of spool 3 ' 1 is connected with drive link 3 ' 2, this drive link 3 ' 2 be connected with the driver blade 3 ' 3 being positioned at cavity of resorption; The outer cover of spool 3 ' 1 is equipped with guide ring 7 ', and the cavity of this guide ring below 7 ' is counter balance pocket 1 ' 4, is provided with and supports the spring 6 ' of spool 3 ' 1 in counter balance pocket 1 ' 4, and this spring 6 ' is to spool 3 ' 1 one elastic force P upwards t.
Using spool 3 ' 1 and drive link 3 ' 2 as force analysis object, spool 3 ' 1 and drive link 3 ' 2 are subject to an elastic force P upwards t, can be subject to the downward thrust that driver blade 3 ' 3 gives, this thrust promotes driver blade 3 ' 3 by diaphragm 2 ' 1 and is formed, thus this thrust that is power that diaphragm 2 ' 1 is moved downward, that is P simultaneously b-P o; When spool 3 ' 1 is in poised state, P b-P o=P t, that is P b=P o+ P t, when the temperature of evaporator outlet end is too high, P bincrease, thus promotion spool 3 ' 1 moves downward, thus increase the flow of refrigerant; When the temperature of evaporator outlet end is too low, P breduce, thus promotion spool 3 ' 1 moves upward, thus reduce the flow of refrigerant.
Although the heating power expansion valve shown in Fig. 1 can realize bidirectional balanced flowing, this balance is only a kind of in a basic balance, and system pressure difference is not entirely zero, does not realize complete equipilibrium.Particularly, as shown in Figure 1, because the connection between driver blade 3 ' 3 and drive link 3 ' 2 is a kind of recessed bond ing, thus in cavity of resorption 2 ' 3 pressure action of refrigerant on the upper surface of drive link 3 ' 2, and then give spool 3 ' 1 one downward active forces, the existence of this active force makes system pressure difference not to be entirely zero, thus still can impact the degree of regulation of spool 3 ' 1.
It should be noted that, that one completes and is tightly connected between driver blade 3 ' 3 and drive link 3 ' 2, therebetween time very close to each other, now with driver blade 3 ' 3, drive link 3 ' 2 and spool 3 ' 1 three entirety are as force analysis object, the active force that now driver blade 3 ' 3 end face one of still can be subject to that refrigerant pressure in cavity of resorption 2 ' 3 produces is downward, the lifting surface area of this active force that is the sealing area between drive link 3 ' 2 and driver blade 3 ' 3, that is the area of the upper surface of drive link 3 ' 2, and then spool 3 ' 1 still can be subject to a downward active force, the existence of this active force makes system pressure difference not to be entirely zero, still can impact the degree of regulation of spool 3 ' 1.
Summary of the invention
The technical problem to be solved in the present invention is for providing a kind of heating power expansion valve, and the structural design of this heating power expansion valve can reduce the system pressure difference that valve hole part is subject to, thus improves the degree of regulation of valve hole part.In addition, another technical problem that will solve of the present invention is for providing a kind of refrigeration system comprising this heating power expansion valve.
Heating power expansion valve disclosed by the invention, comprise the valve body that upper end is provided with gas tank, and the inner chamber of described gas tank is divided into epicoele and cavity of resorption by diaphragm; The valve port being provided with valve hole part in the inner chamber of described valve body and coordinating with described valve hole part, the bottom of described valve body is also provided with the counter balance pocket balancing described valve hole part; The upper end of described valve hole part is located in described cavity of resorption, its bottom is located in the counter balance pocket of described valve body, it is characterized in that, also seal member is provided with between described counter balance pocket and the inner chamber of described valve body, described valve body is also provided with via, the inner chamber of described counter balance pocket and described valve body is by described seal member isolating seal, and described counter balance pocket is communicated with by described via with described cavity of resorption.
Preferably, as the heating power expansion valve of said structure, described via is communicated with described counter balance pocket by the first capillary being located at described valve body outside;
Further, as the heating power expansion valve of said structure, the sidewall of described valve body offers the first installing hole be communicated with described via, and the second installing hole be communicated with described counter balance pocket; One end of described first capillary is located in described first installing hole, and its other end is located in described second installing hole;
Further, as the heating power expansion valve of said structure, the upper end of described valve body is provided with the annular chamber be communicated with cavity of resorption, elastomeric element is provided with in described annular chamber, on the diapire that the bottom of described elastomeric element is supported in described annular chamber or the first spring base, the driver blade that its apical support is connected with described valve hole part;
Further, as the heating power expansion valve of said structure, described annular chamber is communicated with described counter balance pocket by the first capillary;
Preferably, as the heating power expansion valve of said structure, the below of described via is communicated with the connecting hole be integrally processed to form, and described connecting hole is directly communicated with described counter balance pocket;
Further, described counter balance pocket is communicated with the port of export of evaporimeter;
Further, described seal member comprises guiding parts and seal, and described wire guiding member is arranged on the inwall of described valve body by snap ring.
Refrigeration system disclosed by the invention, comprises compressor, heating power expansion valve, evaporimeter and condenser; It is characterized in that, described heating power expansion valve uses the heating power expansion valve of said structure, and described epicoele is connected by the port of export of temperature sensing part with described evaporimeter, and described cavity of resorption is communicated with by the port of export of balance pipe with described evaporimeter.
On the basis of existing technology, the cavity of resorption of the gas tank of heating power expansion valve provided by the present invention is communicated with described counter balance pocket, and described counter balance pocket all with the inner chamber isolating seal of described valve body.Because cavity of resorption is communicated with counter balance pocket, thus the pressure in cavity of resorption and counter balance pocket is equal, thus when under pressure-bearing surface on valve hole part and valve hole part, the projected area of pressure-bearing surface in the plane perpendicular to valve hole part axis is equal, refrigerant in cavity of resorption in refrigerant and counter balance pocket is equal to the amount of force of valve hole part, direction is contrary, thus cancel each other, thus effectively reduce the system pressure difference that valve hole part is subject to.It should be noted that, even if when under the upper pressure-bearing surface and valve hole part of valve hole part, the projected area of pressure-bearing surface in the plane perpendicular to valve hole part axis is unequal, but because the pressure in two cavitys is equal, thus relative to prior art, this kind of structural design also can reduce the system pressure difference that valve hole part is subject to.
In sum, heating power expansion valve provided by the present invention can reduce the system pressure difference that valve hole part is subject to, thus improves the degree of regulation of valve hole part.
In addition, the refrigeration system comprising above-mentioned heating power expansion valve provided by the present invention, its technique effect is substantially identical with the technique effect of above-mentioned heating power expansion valve, does not repeat them here.
Accompanying drawing explanation
Fig. 1 is the structural representation of a kind of typical heating power expansion valve in prior art;
Fig. 2 is the structural representation of heating power expansion valve in the first embodiment of the present invention;
Fig. 3 is the side view of heating power expansion valve in Fig. 2;
Fig. 4 is the structural representation of heating power expansion valve in the second embodiment of the present invention;
Fig. 5 is the side view of heating power expansion valve in Fig. 4;
Fig. 6 is the structural representation of heating power expansion valve in the third embodiment of the present invention;
Fig. 7 is the structural representation of heating power expansion valve in the present invention's the 4th kind of embodiment;
Fig. 8 is the side view of heating power expansion valve in Fig. 7;
Fig. 9 is the structural representation of heating power expansion valve in the present invention's the 5th kind of embodiment;
Figure 10 is the side view of heating power expansion valve in Fig. 9;
Figure 11 is the first capillary mounting structure schematic diagram of heating power expansion valve in the present invention's the 6th kind of embodiment;
Figure 12 is the first capillary mounting structure schematic diagram of heating power expansion valve in the present invention's the 7th kind of embodiment;
Figure 13 is the structural representation of heating power expansion valve in eighth embodiment of the invention;
Figure 14 is the side view of heating power expansion valve in Figure 13;
Detailed description of the invention
Core of the present invention is for providing a kind of heating power expansion valve, and the structural design of this heating power expansion valve can reduce the system pressure difference that valve hole part is subject to, thus improves the degree of regulation of valve hole part.In addition, another core of the present invention is for providing a kind of refrigeration system comprising this heating power expansion valve.
In order to make those skilled in the art understand technical scheme of the present invention better, below in conjunction with the drawings and specific embodiments, the present invention is described in further detail.
First, it should be noted that, " upper and lower, left and right " as herein described are all using position shown in accompanying drawing as reference, thus can not as limiting the scope of the invention.
Please refer to Fig. 2, Fig. 3.Fig. 2 is the structural representation of heating power expansion valve in the first embodiment of the present invention; Fig. 3 is the side view of heating power expansion valve in Fig. 2.
In basic technology scheme of the present invention, as shown in Figure 2, heating power expansion valve comprises valve body 1, the upper end of this valve body 1 is provided with gas tank, this gas tank comprises the gentle case lid 25 of gas tank seat 24, and is provided with diaphragm 21 in gas tank, and the inner chamber of gas tank is divided into epicoele 22 and cavity of resorption 23 by this diaphragm 21; Particularly, as shown in Figure 2, epicoele 22 is connected with temperature sensing part (not shown) by the second capillary 42, and temperature sensing part is located at evaporator outlet end or suction port of compressor end, for experiencing the temperature of this refrigerant herein, and produce a temperature, pressure P in epicoele b; As shown in Figure 3, cavity of resorption 23 is communicated with outer balancing plug 16 by via 15, and this outer balancing plug 16 is communicated with evaporator outlet end or suction port of compressor end further by balance pipe, thus produces an evaporating pressure P in cavity of resorption o.
In addition, as shown in Figure 2, be provided with in the inner chamber of valve body 1 and be formed with valve port 11, this valve port 11 is combined with valve hole part 3, when valve hole part 3 closes with valve port 11, namely when expansion valve cuts out, (those skilled in the art should will be understood that potted line 31 between valve port 11 and valve hole part 3, the i.e. contact site of valve hole part 3 and valve port 11, also sealing surface can be called) inner chamber of separating valve body 1 is that first interface chamber 12 and the second hub cavity 13 (it should be noted that, in the present invention, the intension of the inner chamber of valve body 1 only comprises first interface chamber 12 and the second hub cavity 13), and the upper end of valve hole part 3 is located in cavity of resorption 23, its lower end is located in the counter balance pocket 14 of valve body 1.As shown in Figure 2, guiding parts 7 and seal 71 form seal member, counter balance pocket 14 is by guiding parts 7 and seal 71 provided thereon and the second hub cavity 13 isolating seal, guiding parts passes through jump ring 72 supporting and location on the inwall of valve body, and be provided with elastomeric element 6 in counter balance pocket 14 (to it should be noted that, as shown in Figure 9 and Figure 10, this elastomeric element 6 also can be provided with in the annular chamber 5 of the upper end of valve body 1), these elastomeric element 6 parts give valve hole part 3 one elastic force P upwards t.
Using valve hole part 3 as force analysis object, valve hole part 3 is subject to an elastic force P upwards t, can be subject to the downward thrust that driver blade 32 gives, this thrust promotes driver blade 32 by diaphragm 21 and is formed simultaneously, thus this thrust that is power that diaphragm 21 is moved downward, that is P b-P o; When valve hole part 3 is in poised state, P b-P o=P t, that is P b=P o+ P t, when the temperature of evaporator outlet end is too high, P bincrease, thus promotion valve hole part 3 moves downward, thus increase the flow of refrigerant; When the temperature of evaporator outlet end is too low, P breduce, thus promotion valve hole part 3 moves upward, thus reduce the flow of refrigerant.
On the basis of above-mentioned prior art, the cavity of resorption 23 of the gas tank of heating power expansion valve provided by the present invention is communicated with counter balance pocket 14, and counter balance pocket 14 all with first interface chamber 12 and the second hub cavity 13 isolating seal.Because cavity of resorption 23 is communicated with counter balance pocket 14, thus the pressure in cavity of resorption 23 and counter balance pocket 14 is equal, when the projected area Δ S6 of lower pressure-bearing surface S6 in the plane perpendicular to valve hole part 3 axis of projected area Δ S5 in the plane perpendicular to valve hole part 3 axis of the upper pressure-bearing surface S5 of valve hole part 3 and valve hole part 3 is substantially equal, refrigerant in cavity of resorption 23 in refrigerant and counter balance pocket 14 is equal to the amount of force of valve hole part 3, direction is contrary, thus cancel each other, thus effectively reduce the system pressure difference that valve hole part 3 is subject to.In addition, even if when the upper pressure-bearing surface S5 of valve hole part 3 and the projected area of lower pressure-bearing surface S6 in the plane perpendicular to valve hole part 3 axis of valve hole part 3 unequal time, but because the pressure in two cavitys is equal, thus relative to prior art, this kind of structural design also can reduce the system pressure difference that valve hole part is subject to.It should be noted that, in this article, all " projected area are substantially equal " related to, its intension is except comprising completely equal situation, also comprises the situation of left-right deviation positive and negative 5%.
It should be noted that, the present invention is not restricted for the structure of valve hole part 3, and this valve hole part 3 both can be of the prior art point of body component above, comprised spool 3 ' 1 and drive link 3 ' 2, can also, for the integrated component in Fig. 2 and Fig. 3 of the present invention, can certainly be the structure of other types.
In above-mentioned basic technology scheme, specifically can set the connectivity structure between cavity of resorption 23 and counter balance pocket 14.Particularly, please also refer to Fig. 3, Fig. 4 and Fig. 5, Fig. 4 is the structural representation of heating power expansion valve in the second embodiment of the present invention; Fig. 5 is the side view of heating power expansion valve in Fig. 4.
As shown in Figure 3 and Figure 5, valve body 1 is provided with the via 15 be communicated with cavity of resorption 23, via 15 is connected with outer balancing plug 16, and this outer balancing plug 16 is communicated with evaporator outlet end further by balance pipe, thus realizes being communicated with between cavity of resorption 23 with evaporator outlet end; On this basis, via 15 is communicated with counter balance pocket 14 further.This structural design make use of existing via 15 and designs, and thus makes the connectivity structure between cavity of resorption 23 and counter balance pocket 14 become easy.
Particularly, as shown in Figure 5, the below of via 15 is communicated with the connecting hole 151 be integrally processed to form, and connecting hole 151 is directly communicated with counter balance pocket 14.In this structural design, via 15 and connecting hole 151 are integrally processed to form in same procedure, also directly punch counter balance pocket 14 by connecting hole 151, thus realize being communicated with between cavity of resorption 23 with counter balance pocket 14.Obviously, this kind of structural design further simplify the connectivity structure between cavity of resorption 23 and counter balance pocket 14, reduces processing cost.
In addition, on the basis of via 15, another kind of connectivity structure can also be adopted.Such as, as shown in Figure 3, the below of via 15 is communicated with the connecting hole 151 be integrally processed to form, and connecting hole 151 is communicated with counter balance pocket 14 by the first capillary 41 being located at valve body 1 outside.Stating in technical scheme shown in Fig. 5, connecting hole 151 directly punches the structure of counter balance pocket 14, although connectivity structure is very simple, because axial dimension is comparatively large, and aperture is less, causes processing to get up comparatively difficulty.And in the technical scheme shown in Fig. 3, connecting hole 151 does not punch counter balance pocket 14, but be communicated with counter balance pocket 14 further by the first capillary 41, thus make the processing of connecting hole 151 become easy.
On the basis of above-mentioned connectivity structure, further improvement can also be made.Please refer to Figure 11 and Figure 12, Figure 11 is the first capillary mounting structure schematic diagram of heating power expansion valve in the present invention's the 6th kind of embodiment; Figure 12 is the first capillary mounting structure schematic diagram of heating power expansion valve in the present invention's the 7th kind of embodiment.
Particularly, the sidewall of valve body 1 offers the first installing hole 17 be communicated with connecting hole 151, and the second installing hole 18 be communicated with counter balance pocket 14; One end of first capillary 41 is located in the first installing hole 17, and its other end is located in the second installing hole 18.
Further, as shown in figure 11, when gas tank seat 24 under, valve body 1 upper or valve body 1 upper, gas tank seat 24 under time, the first installing hole 17 and the second installing hole 18 are all obliquely installed in its inner outer end mode upwards downwards.This kind of structural design can so that before being welded and fixed, and the first capillary 41 is hung in the first installing hole 17 and the second installing hole 18, prevents it from coming off, thus is convenient to the assemble welding between the first capillary 41 and valve body 1.In addition, as shown in figure 12, when gas tank seat 24 under, valve body 1 upper or valve body 1 upper, gas tank seat 24 under time, the sidewall of valve body 1 is equipped with the inclined-plane 19 that inside lower end, upper end is outside, as shown in Figure 2, the angle of this inclined-plane and valve axis is θ, and the first capillary 41 is attached on this inclined-plane 19.The structural design on this inclined-plane 19 can be formed the first capillary 41 and support, thus prevents it from coming off from the first installing hole 17 and the second installing hole 18.
Further; as is illustrated by figs. 11 and 12, the sidewall of valve body 1 can be provided with capillary slot 43, the first capillary 41 is located in capillary slot 43; this capillary slot 43 can play a protective role to the first capillary 41, thus prevents the first capillary 41 to be damaged.
Please refer to Fig. 6, Fig. 6 is the structural representation of heating power expansion valve in the third embodiment of the present invention.
In this embodiment, the upper pressure-bearing surface S5 of valve hole part 3 and driver blade 32 are recessed bond ing; On this basis, valve hole part 3 offers valve hole part through hole 33 vertically, and cavity of resorption 23 is communicated with counter balance pocket 14 by valve hole part through hole 33.Obviously, this kind of structural design also can realize the object being communicated with cavity of resorption 23 and counter balance pocket 14.
Please refer to Fig. 9 and Figure 10, Fig. 9 is the structural representation of heating power expansion valve in the present invention's the 5th kind of embodiment; Figure 10 is the side view of heating power expansion valve in Fig. 9.
On the basis of any one technical scheme above-mentioned, further improvement can also be made.Such as, elastomeric element 6 can be located at the upper end of valve body 1.Particularly, as shown in Figure 9 and Figure 10, the upper end of valve body 1 is provided with annular chamber 5, and this annular chamber 5 is communicated with cavity of resorption 23; Be provided with elastomeric element 6 in annular chamber 5, the bottom of elastomeric element 6 is supported on the diapire of annular chamber 5, the driver blade 32 that its apical support is connected with valve hole part 3.As shown in Figure 9 and Figure 10, this kind of structural design makes elastomeric element 6 be set in the outside of valve hole part 3 by annular chamber 5, thus relative to the heating power expansion valve in other embodiments of the invention, decrease the axial dimension that valve hole part 3 assembles with elastomeric element 6, and then decrease the axial dimension of heating power expansion valve, achieve the object of heating power expansion valve volume miniaturization.
Further, in the above-described embodiments, annular chamber 5 is communicated with counter balance pocket 14 further by the first capillary 41, thus achieves being communicated with between cavity of resorption 23 with counter balance pocket 14.This kind of structural design avoids the structural design of connecting hole 151, and thus connectivity structure becomes simple.
In addition, as shown in Figure 9 and Figure 10, the diapire of annular chamber 5 is provided with the first spring base 61 supporting elastomeric element 6, obviously by the first spring base 61 of assembling different-thickness, can the elastic force of adjustable elastic parts 6, and then the degree of superheat of heating power expansion valve can be adjusted.
As shown in Figure 9 and Figure 10, be provided with the guiding parts 7 being placed on valve hole part 3 outside in the inner chamber of valve body 1 bottom, counter balance pocket 14 is by guiding parts 7 and the seal 71 be located on guiding parts 7 and the second hub cavity 13 isolating seal; The lower openings of counter balance pocket 14 has been threaded bonnet 81, and bonnet 81 support guide parts 7.By bonnet 81 directly supporting and location guiding parts 7, the jump ring 72 that supporting and location guiding parts 7 is set again can be avoided, thus decrease parts, reduce parts expenditure cost and assembly cost.
Moreover, as shown in Figure 9 and Figure 10, be provided with in the outside of counter balance pocket 14 inner spool parts 3 bottom the gripping grove 34 being convenient to holder.This gripping grove 34 and valve body 1 time pressure-bearing surface is concordant or substantially concordant, or higher than the lower pressure-bearing surface of valve body 1, thus facilitate fixture clamping.After fixture clamping, can valve opening position elasticity of compression parts 6 in the past, the assembly such as diaphragm 21, gas tank lid 25 can be facilitated to carry out assemble welding.
Please refer to Fig. 7 and Fig. 8, Fig. 7 is the structural representation of heating power expansion valve in the present invention's the 4th kind of embodiment; Fig. 8 is the side view of heating power expansion valve in Fig. 7.
This kind of embodiment is substantially identical with the technical scheme shown in Fig. 2 with Fig. 3, and difference is: elastomeric element 6 is directly supported by bonnet 81, and thus elastomeric element 6 is non-adjustable.Because elastomeric element 6 is non-adjustable, thus the degree of superheat of heating power expansion valve is non-adjustable.
And in the technical scheme shown in Fig. 2, Fig. 4 and Fig. 6, the bottom of valve body 1 is equipped with adjustment seat 82, adjusting rod 83 is provided with in this adjustment seat 82, the upper end of this adjusting rod 83 has been threaded the second spring base 62, this second spring base 62 supports elastomeric element 6, the upper end of elastomeric element 6 is further by the 3rd spring base 63 sutaining valve core components 3, and the lower end of adjustment seat 82 is combined with bonnet 81.Positive and negative both direction rotation adjusting lever 83, can screw or loosen elastomeric element 6, thus regulates the degree of superheat of heating power expansion valve.
Please refer to Figure 13 and Figure 14, Figure 13 is the structural representation of heating power expansion valve in eighth embodiment of the invention; Figure 14 is the side view of heating power expansion valve in Figure 13.
In this embodiment, as shown in Figure 13 and Figure 14, valve hole part 3 is Split type structure, comprises epimere 36, stage casing 37 and hypomere 38.Certainly, further, driver blade 32 and epimere 36 can be structure as a whole, and now driver blade 32 can think a part for valve hole part 3.
It should be noted that at this, in any one embodiment above-mentioned, upper pressure-bearing surface S5 is the cross section perpendicular to its axis at seal 35 position valve hole part 3; Lower pressure-bearing surface S6 is the cross section perpendicular to its axis at seal 71 position valve hole part 3; As shown in Figure 13 and Figure 14, upper pressure-bearing surface S5 is also the cross section of seal 35 position epimere 36 perpendicular to its axis, and lower pressure-bearing surface S6 is also the cross section of seal 71 position hypomere 38 perpendicular to its axis.
In addition, the present invention also provides a kind of refrigeration system, comprises compressor, heating power expansion valve, evaporimeter and condenser; Described heating power expansion valve is the heating power expansion valve in any one embodiment above-mentioned, and epicoele 22 is connected by the port of export of temperature sensing part with described evaporimeter, and described cavity of resorption 23 is communicated with by the port of export of balance pipe with described evaporimeter; This refrigeration system is specifically as follows heat pump or air-conditioning, and other parts of described refrigeration system with reference to prior art, no longer can be launched herein.
Above refrigeration system provided by the present invention and heating power expansion valve thereof are described in detail.Apply specific case herein to set forth principle of the present invention and embodiment, the explanation of above embodiment just understands method of the present invention and core concept thereof for helping.It should be pointed out that for those skilled in the art, under the premise without departing from the principles of the invention, can also carry out some improvement and modification to the present invention, these improve and modify and also fall in the protection domain of the claims in the present invention.

Claims (9)

1. a heating power expansion valve, comprise the valve body (1) that upper end is provided with gas tank, and the inner chamber of described gas tank is divided into epicoele (22) and cavity of resorption (23) by diaphragm (21); The valve port (11) being provided with valve hole part (3) in the inner chamber of described valve body (1) and coordinating with described valve hole part (3), the bottom of described valve body (1) is also provided with the counter balance pocket (14) of the described valve hole part of balance (3); The upper end of described valve hole part (3) is located in described cavity of resorption (23), its bottom is located in the counter balance pocket (14) of described valve body (1), it is characterized in that, also seal member is provided with between described counter balance pocket (14) and the inner chamber of described valve body (1), described valve body (1) is also provided with via (15), described counter balance pocket (14) passes through described seal member isolating seal with the inner chamber of described valve body (1), and described counter balance pocket (14) is communicated with by described via (15) with described cavity of resorption (23).
2. heating power expansion valve as claimed in claim 1, is characterized in that, described via (15) is communicated with described counter balance pocket (14) by the first capillary (41) being located at described valve body (1) outside.
3. heating power expansion valve as claimed in claim 2, it is characterized in that, the sidewall of described valve body (1) offers the first installing hole (17) be communicated with described via (15), and the second installing hole (18) be communicated with described counter balance pocket (14); One end of described first capillary (41) is located in described first installing hole (17), and its other end is located in described second installing hole (18).
4. heating power expansion valve as claimed in claim 2, it is characterized in that, the upper end of described valve body (1) is provided with the annular chamber (5) be communicated with cavity of resorption (23), elastomeric element (6) is provided with in described annular chamber (5), on the diapire that the bottom of described elastomeric element (6) is supported in described annular chamber (5) or the first spring base (61), its apical support is in the driver blade (32) be connected with described valve hole part (3).
5. heating power expansion valve as claimed in claim 4, it is characterized in that, described annular chamber (5) is communicated with described counter balance pocket (14) further by the first capillary (41).
6. heating power expansion valve as claimed in claim 1, it is characterized in that, the below of described via (15) is communicated with the connecting hole (151) be integrally processed to form, and described connecting hole (151) is directly communicated with described counter balance pocket (14).
7. the heating power expansion valve as described in any one of claim 1-6, is characterized in that, described counter balance pocket (14) is communicated with the port of export of evaporimeter.
8. the heating power expansion valve as described in any one of claim 1-6, it is characterized in that, described seal member comprises guiding parts (7) and seal, and described guiding parts (7) is arranged on the inwall of described valve body (1) by snap ring.
9. a refrigeration system, comprises compressor, heating power expansion valve, evaporimeter and condenser; It is characterized in that, described heating power expansion valve is the heating power expansion valve as described in any one of claim 1 to 6, described epicoele (22) is connected by the port of export of temperature sensing part with described evaporimeter, and described cavity of resorption is communicated with by the port of export of balance pipe with described evaporimeter.
CN201110026552.6A 2011-01-14 2011-01-14 Refrigeration system and thermostatic expansion valve thereof Active CN102589207B (en)

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CN102589207A CN102589207A (en) 2012-07-18
CN102589207B true CN102589207B (en) 2015-07-01

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Publication number Priority date Publication date Assignee Title
CN103807480B (en) * 2012-11-12 2017-06-20 浙江盾安禾田金属有限公司 A kind of heating power expansion valve
CN104344611B (en) * 2013-08-08 2018-01-26 盾安环境技术有限公司 A kind of expansion valve
CN104748457B (en) * 2013-12-27 2017-12-15 浙江三花制冷集团有限公司 A kind of heating power expansion valve and its core assembly
CN105805989B (en) * 2014-12-29 2019-01-29 浙江三花制冷集团有限公司 Heating power expansion valve
CN107782022A (en) * 2016-08-31 2018-03-09 天津天阳时代科技股份有限公司 A kind of heating power expansion valve

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GB1256117A (en) * 1968-06-03 1971-12-08 Universal American Corp Refrigeration system
CN2789522Y (en) * 2005-03-16 2006-06-21 浙江三花制冷集团有限公司 Thermal expansion valve easy to introduce membrane balance medium
CN1834506A (en) * 2005-03-16 2006-09-20 浙江三花制冷集团有限公司 Top arranged thermal expansion valve of regulation spring
CN201359097Y (en) * 2009-03-12 2009-12-09 浙江春晖智能控制股份有限公司 Inner balance bidirectional thermal expansion valve
CN101788064A (en) * 2009-01-24 2010-07-28 丹佛斯(天津)有限公司 Valve

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GB1256117A (en) * 1968-06-03 1971-12-08 Universal American Corp Refrigeration system
CN2789522Y (en) * 2005-03-16 2006-06-21 浙江三花制冷集团有限公司 Thermal expansion valve easy to introduce membrane balance medium
CN1834506A (en) * 2005-03-16 2006-09-20 浙江三花制冷集团有限公司 Top arranged thermal expansion valve of regulation spring
CN101788064A (en) * 2009-01-24 2010-07-28 丹佛斯(天津)有限公司 Valve
CN201359097Y (en) * 2009-03-12 2009-12-09 浙江春晖智能控制股份有限公司 Inner balance bidirectional thermal expansion valve

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