CN110541962A - Memory alloy thermostatic valve core adopting downward hot water inlet - Google Patents

Abstract

The invention discloses a memory alloy thermostatic valve core adopting downward hot water feeding, which comprises a valve core upper body and a valve core lower body connected with the valve core upper body, wherein a slide block, an upper half part of a memory alloy spring sleeve and a lower half part of the memory alloy spring sleeve in threaded connection with the upper half part are arranged in an inner cavity of the valve core lower body, a mandril and a memory alloy spring are arranged in the inner cavity of the memory alloy spring sleeve, a bias spring is arranged between the outer wall of the lower half part of the memory alloy spring sleeve and the valve core lower body, and a circular step is arranged at the bottom of. The invention is characterized in that the water is fed with cold water and hot water from the upper part, the memory alloy spring is not in direct contact with the cold water or the hot water and is always in a temperature field of mixed water, and the phenomenon that the cold water and the hot water are not fully mixed and the temperature control is unstable when the thermostatic valve core works is solved.

Description

memory alloy thermostatic valve core adopting downward hot water inlet

Technical Field

The invention relates to a valve core, in particular to a memory alloy thermostatic valve core adopting downward hot water feeding, which is suitable for memory alloy thermostatic valve cores of shower facilities.

background

the paraffin wax thermal bulb is mostly used as a thermosensitive element in the existing thermostatic valve core. The disadvantages are:

firstly, a sealing element required by paraffin drive belongs to a vulnerable part, occupies a large space, loses the temperature control effect after being damaged, and has a large potential safety hazard;

Secondly, the temperature range of the paraffin drive is narrow, and the paraffin drive is suddenly released during driving, so that the temperature jump change is easily caused, and the bath comfort is influenced.

In addition, the current memory alloy thermostatic valve core of bathroom trade structurally cold, the position of hot water inlet is cold from top to bottom for hot, and is inconsistent with traditional paraffin case, when the hot water inlet was on case upper portion, on the heat can conduct the adjustment handle, people carelessly can scald a little. In addition, the design of the water channel and the appearance of the existing thermostatic faucet on the market are mostly designed according to the hot water inlet under the valve core and the cold water inlet on the valve core, including the use habits of people, so that little resistance exists in the production, the sale and the use. There is therefore a need for an improvement to existing memory alloy thermostatic cartridges.

Disclosure of Invention

the invention aims to solve the technical problem of providing a memory alloy thermostatic valve core adopting downward hot water feeding, which can simplify the structural design of a valve body and reduce the volume, and better solves the problems that cold water and hot water are not sufficiently mixed, and the temperature control effect under the conditions of cold water pressure fluctuation and current limiting can not reach the domestic and foreign standards by adjusting the compression amount of a memory alloy spring, changing the flow direction of cold water and hot water in the valve core and optimizing a mixed water channel.

In order to solve the technical problems, the invention adopts the following technical scheme: the improved water heater comprises a valve core upper body and a valve core lower body connected with the valve core upper body, wherein an inner cavity of the valve core upper body is provided with an adjusting knob and an adjusting block, the adjusting knob and the adjusting block are connected through threads, a cold water inlet, a hot water inlet and a mixed water outlet are sequentially arranged on the side wall of the valve core lower body from top to bottom, an ejector rod, a slider and a memory alloy spring sleeve are arranged in the inner cavity of the valve core lower body, a memory alloy spring is arranged in the inner cavity of the memory alloy spring sleeve, the memory alloy spring sleeve comprises an upper half part and a lower half part, a bias spring is arranged between the outer wall of the lower half part of the.

Furthermore, grooves are formed in the top and the bottom of the sliding block, and three through special-shaped holes are uniformly distributed in the grooves.

further, the sliding block is in threaded connection with the upper half part of the memory alloy spring sleeve.

Furthermore, the lower half part of the memory alloy spring sleeve is in threaded connection with the upper half part of the memory alloy spring sleeve, and a rectangular hole is formed in the side wall of the bottom of the lower half part of the memory alloy spring sleeve.

Furthermore, three fan-shaped holes are uniformly formed in a disc shape at the bottom of the ejector rod, and the top end of the long rod part of the ejector rod abuts against a positioning hole formed in the adjusting block.

Furthermore, the long rod part of the ejector rod penetrates through a threaded inner hole at the upper end of the upper half part of the memory alloy spring sleeve and a gap for mixed water to pass through is reserved.

Further, the bottom of the bias spring is positioned in a circular step of the lower body of the valve core for limiting.

Furthermore, a first sealing ring and a second sealing ring are arranged between the circumferential direction of the adjusting knob and the valve core upper body.

Further, a third sealing ring is arranged between the sliding block and the lower body of the valve core.

Furthermore, a fourth sealing ring is arranged between the upper half part of the memory alloy spring sleeve and the lower body of the valve core, and guides hot water into the special-shaped hole of the sliding block and flows upwards the sliding block to meet with cold water.

Furthermore, the upper valve core body is provided with a fifth sealing ring, the lower valve core body is provided with a sixth sealing ring and a seventh sealing ring, the mixed water outlet is positioned between the seventh sealing ring and the inner bottom surface of the lower valve core body, the fifth sealing ring and the sixth sealing ring seal cold water and isolate the cold water from hot water, the sixth sealing ring and the seventh sealing ring seal hot water and isolate the cold water from the mixed water, and the seventh sealing ring isolates the mixed water from the hot water.

Furthermore, the outer wall of the bottom of the lower half part of the memory alloy spring sleeve is in clearance fit with the central through hole of the bottom of the lower body of the valve core.

Compared with the prior art, the invention has the beneficial effects that:

1. The structure design is optimized, the ejector rod penetrates through the sliding block to achieve the adjusting effect on the compression amount of the memory alloy spring, the memory alloy spring is arranged in the memory alloy spring sleeve, hot water is prevented from directly washing the memory alloy spring, the hot water is guided to the upper portion of the sliding block through the sealing ring arranged on the upper half portion of the memory alloy spring sleeve, the hot water and cold water are mixed, mixed water flows into an inner cavity formed by the upper half portion of the memory alloy spring sleeve and the ejector rod long rod through a reserved gap between the central hole of the upper half portion of the memory alloy spring sleeve and the ejector rod long rod and then flows out, the memory alloy spring is always located in a stable temperature field of the mixed water, and the temperature control.

2. The ejector rod is matched with the upper part and the lower part of the memory alloy spring sleeve, and the memory alloy spring enables the sliding block and the memory alloy spring sleeve to integrally bear downward thrust. The bias spring is arranged outside the memory alloy spring, so that the sliding block and the memory alloy spring sleeve are integrally stressed by upward force, and the memory alloy spring and the bias spring are arranged on the same side, thereby saving the upper half space of the thermostatic valve core, simplifying the structure, reducing the volume and lowering the cost.

3. hot water is fed under the thermostatic valve element, the appearance of the thermostatic valve element is completely consistent with that of the existing paraffin wax thermometer bulb thermostatic valve element, the existing paraffin wax thermometer bulb thermostatic valve element on the market can be replaced, and the market popularization is easy.

Drawings

FIG. 1a is a schematic cross-sectional view of one embodiment of a memory alloy thermostatic cartridge of the present invention;

FIG. 1b is an exploded view of one embodiment of the memory alloy thermostatic cartridge of the present invention;

FIG. 2 is a schematic view of the conditioning block of FIG. 1 a;

FIG. 3 is a schematic view of the slider of FIG. 1 a;

FIG. 4 is a top view corresponding to FIG. 3;

FIG. 5 is a schematic view of the stem lifter of FIG. 1 a;

FIG. 6 is a top view corresponding to FIG. 5;

FIG. 7 is a schematic view of the upper half of the memory alloy spring case of FIG. 1 a;

FIG. 8 is a schematic view of the memory alloy spring housing of FIG. 1 a;

Fig. 9 is a side view corresponding to fig. 8.

Description of the reference numerals

1-adjusting knob; 2-valve core upper body; 3-a regulating block; 4-a top rod; 5-a cold water inlet; 6-a slide block; 7-hot water inlet; 8-the upper half part of the memory alloy spring sleeve; 9-a memory alloy spring; 10-valve core lower body; 11-the lower half part of a memory alloy spring sleeve; 12-a biasing spring; 13-a first sealing ring; 14-a second sealing ring; 15-a third sealing ring; 16-a fourth seal ring; 17-a fifth sealing ring; 18-sixth sealing ring; 19-a seventh sealing ring; 20-mixed water outlet; 21-a mixing chamber; 22-a shaped pore; 23-a fan-shaped hole; 24-rectangular hole.

Detailed Description

The invention is described in further detail below with reference to the figures and the examples, but without limiting the invention.

Referring to fig. 1a and 1b in combination with fig. 2 to 9, the memory alloy thermostatic valve core of the present invention includes a valve core upper body 2 and a valve core lower body 10 connected thereto, an adjusting knob 1 and an adjusting block 3 in threaded connection with the adjusting knob are arranged in the inner cavity of the valve core upper body 2, a cold water inlet 5, a hot water inlet 7 and a mixed water outlet 20 are sequentially arranged on the side wall of the valve core lower body 10 from top to bottom, the inner cavity of the valve core lower body 10 is provided with a mandril 4, a slide block 6, an upper half part 8 of a memory alloy spring sleeve and a lower half part 11 of the memory alloy spring sleeve which is connected with the upper half part by screw thread, the inner cavity of the upper and lower parts of the memory alloy spring sleeve is provided with a memory alloy spring 9, a bias spring 12 is arranged between the outer wall of the lower part 11 of the memory alloy spring sleeve and the lower valve core body 10, and the bottom of the lower valve core body 10 is provided with a circular step which is described below respectively.

According to the memory alloy thermostatic valve core provided by the invention, the memory alloy spring sleeve is designed into an upper part and a lower part, the outer wall of the upper part of the memory alloy spring sleeve is provided with the sealing ring, hot water flows to the upper part of the guide sliding block and is fully mixed with cold water and then flows into the inner cavity formed by the upper part and the lower part of the memory alloy spring sleeve, the memory alloy spring generates reverse thrust through the ejector rod and finally pushes the sliding block to move downwards, the bias spring is arranged on the outer wall of the lower part of the memory alloy spring sleeve, and the sliding block is pushed to move upwards through the bottom end of the upper.

The invention overcomes the difficulty that the hot water inlet of the memory alloy thermostatic valve core is difficult to be arranged at the lower part, so that the memory alloy spring is always in the environment of mixed water, and the performance of the memory alloy spring is fully exerted.

With continued reference to fig. 1a and 1b, an inner cavity of the valve core upper body 2 is provided with an adjusting knob 1 and an adjusting block 3 in threaded connection with the adjusting knob, and the adjusting knob 1 is sealed by a first sealing ring 13 and a second sealing ring 14. The top of the adjusting block 3 is connected with the bottom of the adjusting knob 1 through a multi-start thread. Referring to fig. 2, the bottom of the adjusting block is provided with a mounting hole.

As shown in figures 1a and 1b, the inner cavity of the lower body of the valve core is provided with a slide block 6, a mandril 4, an upper half part 8 of a memory alloy spring sleeve and a lower half part 11 of the memory alloy spring sleeve. Referring to fig. 3 and 4, the top and the bottom of the slider 6 are both provided with grooves, three through holes 22 are uniformly distributed on the circumference of the grooves, and hot water enters the valve body from the hot water inlet 7 and flows into the mixing chamber 21 through the three holes 22 on the slider 6. And a third sealing ring 15 is arranged between the sliding block 6 and the valve core lower body 10 and is used for isolating cold water and hot water. Referring to fig. 7, the upper half 8 of the memory alloy spring housing is in a shape of a Chinese character ji, the top of the memory alloy spring housing is provided with threads connected with the central threaded hole of the slider 6, and a fourth sealing ring 16 is arranged between the sidewall of the upper half 8 of the memory alloy spring housing and the lower body 10 of the valve core for guiding hot water to the upper part of the guide slider 6 and isolating hot water and mixed water. The side wall of the lower half portion 11 of the memory alloy spring sleeve is provided with threads and is connected with the upper half portion 8 of the memory alloy spring sleeve to wrap the memory alloy spring 9, the fourth sealing ring 16 on the upper half portion 8 of the memory alloy spring sleeve enables hot water to flow to the upper portion of the sliding block 6 to meet and mix with cold water, direct hot water flushing is avoided, the memory alloy spring 9 is guaranteed to be always located in a stable temperature field of mixed water, and the stability of temperature control is improved.

Continuing to show in fig. 1a and 1b, a top rod 4 is arranged in the cavity of the upper half part 8 of the memory alloy spring sleeve, and the tail end of the top rod 4 penetrates into the mounting hole at the bottom of the adjusting block 3 through the central holes of the upper half part 8 of the memory alloy spring sleeve and the sliding block 6. Referring to fig. 5 and 6, three fan-shaped holes 23 are uniformly distributed in the circumferential direction at the bottom of the ejector rod 4, and hot water and cold water are mixed in the mixing chamber 21, pass through a gap reserved between the long rod part of the ejector rod 4 and the central hole of the upper half part 8 of the memory alloy spring sleeve, and flow into a chamber formed by the upper part and the lower part of the memory alloy spring sleeve through the three fan-shaped holes 23 at the bottom of the ejector rod 4. The memory alloy spring 9 is arranged in an inner cavity formed by the upper part and the lower part of the memory alloy spring sleeve, and as shown in fig. 8 and 9, two rectangular holes 24 are formed in the side part of the bottom of the lower half part 11 of the memory alloy spring sleeve and used for mixed water to flow out. The lower half part 11 of the memory alloy spring sleeve is in clearance fit with the central hole at the bottom of the lower body 10 of the valve core, and does not interfere with each other when moving up and down axially.

In this embodiment, the biasing spring 12 is located between the lower half 11 of the memory alloy spring housing and the lower valve element body 10 to apply an elastic force to the upper half 8 of the memory alloy spring housing, and the biasing spring 12 is limited by a circular step at the bottom of the lower valve element body 10.

As shown in fig. 1a and 1b, a push rod 4, a slide block 6, an upper half portion 8 of a memory alloy spring sleeve, a lower half portion 11 of the memory alloy spring sleeve, and a 9-stage bias spring 12 of the memory alloy spring form a bias structure in the valve body, the bias structure is driven by an adjusting knob 1, an adjusting block 3 can move axially up and down, the adjusting block 3 generates displacement when moving up and down, the compression amount of the memory alloy spring 9 is adjusted through the push rod 4, and the slide block 6 is connected with the upper half portion 8 of the memory alloy spring sleeve and the lower half portion 11 of the memory alloy spring sleeve, the push rod 4 and the memory alloy spring 9 generate elastic force to move axially up and down to change the sizes of channels of a cold water inlet 5 and.

As shown in figure 1, hot water can only flow through the special-shaped hole 22 on the slide block 6 through the hot water inlet 7 to enter the mixing cavity 21 of the upper body of the valve core, cold water enters the mixing cavity 21 through the cold water inlet 5, the cold water and the hot water are fully mixed in the mixing cavity 21 and then flow into a cavity formed by the upper part and the lower part of the memory alloy spring through a gap reserved between the long rod of the ejector rod 4 and the central hole of the upper part 8 of the memory alloy spring sleeve, meanwhile, the memory alloy spring 9 generates elastic force change through the change of the temperature of the mixed water, so that the slide block 6 is adjusted up and down, the size of a channel of the cold water inlet 5 and the size of a channel.

In addition, the upper valve core body 2 is provided with a fifth sealing ring 17, the lower valve core body 10 is provided with a sixth sealing ring 18 and a seventh sealing ring 19, a mixed water outlet 20 is positioned between the seventh sealing ring 19 and the inner bottom surface of the lower valve core body 10, the fifth sealing ring 17 and the sixth sealing ring 18 seal cold water and isolate the cold water from hot water, the sixth sealing ring 18 and the seventh sealing ring 19 seal hot water and isolate the cold water and the mixed water, and the seventh sealing ring 19 isolates the mixed water from the hot water.

When the invention is assembled, the valve bodies and the temperature control assembly are installed in sequence:

1. The sliding block 6 is integrally installed with the upper half part 8 of the memory alloy spring sleeve through threads, the ejector rod 4 and the memory alloy spring 9 are sequentially placed in an inner cavity of the upper half part 8 of the memory alloy spring sleeve, and the lower half part 11 of the memory alloy spring sleeve is connected with the upper half part 8 of the memory alloy spring sleeve through threads;

2. Placing the bias spring 12 and the assembled slide block 6 into the lower valve body 10;

3. The valve core upper body 2 and the adjusting knob 1 are fixed through a clamp spring, and the adjusting block 3 is connected and installed into a whole by means of multi-start threads on the adjusting knob 1;

4. and (4) matching the assembled valve core lower body 8 with the valve core upper body 2 through threads, and finishing installation.

The water flow direction of the invention is as follows: cold water enters the mixing cavity 21 of the upper valve core body 2 through the cold water inlet 5, hot water enters the lower valve core body 10 through the hot water inlet 7, and the hot water is mixed with the cold water in the mixing cavity 21 through the through special-shaped hole 22 of the sliding block 5. The mixed water flows into a cavity formed by the upper part and the lower part of the memory alloy spring through a gap reserved between the long rod part of the ejector rod 4 and the central hole of the upper half part 8 of the memory alloy spring sleeve, flows out through a rectangular hole 24 on the side wall of the bottom of the memory alloy spring sleeve and finally flows out through a mixed water outlet 20.

After the water outlet temperature is set, the biasing structure is balanced in force. Since the water outlet temperature is set within the characteristic range of the memory alloy spring 9, if the water temperature fluctuates due to some reasons such as sudden changes of water supply pressure and temperature, the elastic modulus of the memory alloy spring 7 changes greatly, which causes the corresponding change of the force of the memory alloy spring 9, thereby breaking the original force balance and pushing the slide block 6 to move axially up and down to change the ratio of cold water and hot water entering. Because of adopting negative feedback control, the outlet water temperature of the thermostatic valve is quickly and automatically restored to be close to the original temperature needing to be controlled, and new balance is reestablished at the temperature so as to keep the outlet water temperature constant.

the invention uses the memory alloy spring, which not only can simplify the structural design of the valve body, reduce the volume of the valve to the maximum extent, save raw materials, but also can realize the near linear intelligent drive in a large temperature range, avoid the discomfort condition caused by temperature change, and improve the safety, comfort and intelligence of the temperature control valve and prolong the service life. The valve core of the invention is easy to process, has good batch stability and consistency, and can be interchanged with paraffin constant temperature valve cores which exist in large quantities on the market at present. The invention well solves the problems that cold water and hot water can not be fully mixed and the memory alloy spring is in a stable temperature field by adjusting the compression amount of the memory alloy spring, changing the flow direction of cold water and hot water in the valve core and optimizing a mixed water channel, thereby realizing the aim of stable temperature control and temperature return and effectively solving the phenomena of unstable temperature control performance and various performances of the valve core caused by the pressure change of the cold water and the hot water and the limitation of water outlet flow.

The above embodiments are only exemplary embodiments of the present invention, and are not intended to limit the present invention, and the scope of the present invention is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present invention, and such modifications and equivalents should also be considered as falling within the scope of the present invention.

Claims (12)

1. the utility model provides an adopt hot water's memory alloy thermostatic valve core down, includes the case upper part of the body and rather than the case lower part of the body of being connected, its characterized in that, case upper part of the body inner chamber is provided with adjust knob and regulating block, adjust knob and regulating block pass through threaded connection, the lateral wall top-down of the case lower part of the body has set gradually cold water import, hot water import and mixed water export, be provided with ejector pin, slider and memory alloy spring housing in the case lower part of the body inner chamber, memory alloy spring housing inner chamber is provided with the memory alloy spring, the memory alloy spring housing includes first half and latter half, be provided with biasing spring between the outer wall of memory alloy spring housing latter half and the case lower part of the body, case lower part of the body.

2. The memory alloy thermostatic valve core according to claim 1, wherein the top and the bottom of the slider are both provided with grooves, and three through profiled holes are uniformly distributed on the grooves.

3. The memory alloy thermostatic valve cartridge according to claim 1, wherein the slider is threadedly coupled to the upper half of the memory alloy spring housing.

4. the memory alloy thermostatic valve core according to claim 1, wherein the lower half portion of the memory alloy spring sleeve is in threaded connection with the upper half portion of the memory alloy spring sleeve, and a rectangular hole is formed in the side wall of the bottom of the lower half portion of the memory alloy spring sleeve.

5. the memory alloy thermostatic valve core according to claim 1, wherein three fan-shaped holes are uniformly formed in a disc shape at the bottom of the ejector rod, and the top end of the long rod part of the ejector rod abuts against a positioning hole formed in the adjusting block.

6. The memory alloy thermostatic valve core according to claim 1, wherein the long rod part of the ejector rod penetrates through a threaded inner hole at the upper end of the upper half part of the memory alloy spring sleeve and is reserved with a gap for mixed water to pass through.

7. the memory alloy thermostatic cartridge of claim 1, wherein the bottom of the biasing spring is seated within a circular step of the cartridge lower body for limiting.

8. The memory alloy thermostatic valve cartridge according to claim 1, wherein a first sealing ring and a second sealing ring are arranged between the circumferential direction of the adjusting knob and the valve cartridge upper body.

9. The memory alloy thermostatic valve cartridge of claim 1, wherein a third sealing ring is disposed between the slider and the valve cartridge lower body.

10. The memory alloy thermostatic valve cartridge of claim 1, wherein a fourth sealing ring is disposed between the upper half of the memory alloy spring sleeve and the lower half of the valve cartridge to guide hot water into the profiled bore of the slider and to meet cold water upward of the slider.

11. The memory alloy thermostatic valve cartridge of claim 1, wherein the upper body of the valve cartridge is provided with a fifth sealing ring, the lower body of the valve cartridge is provided with a sixth sealing ring and a seventh sealing ring, the mixed water outlet is located between the seventh sealing ring and the inner bottom surface of the lower body of the valve cartridge, the fifth sealing ring and the sixth sealing ring seal cold water and isolate hot water, the sixth sealing ring and the seventh sealing ring seal hot water and isolate cold water and mixed water, the seventh sealing ring isolates mixed water and hot water.

12. The memory alloy thermostatic valve cartridge according to any one of claims 1 to 10, wherein the outer wall of the bottom of the lower half portion of the memory alloy spring housing is in clearance fit with the central through hole of the bottom of the lower body of the valve cartridge.