ES2955516T3 - Dry ice smoke generator - Google Patents

Abstract

A smoke generator includes a housing having a first chamber that receives dry ice, a second chamber that receives water, and a third chamber. The housing includes an exterior side that has a smoke outlet that communicates with the second chamber. The first chamber includes a smoke discharge port that interfaces with the second chamber. A water pump device in the third compartment includes a water inlet located in the second chamber and a water spray end located in the first chamber. The water pump device supplies water from the second chamber to the first chamber. Dry ice comes into contact with water and gasifies forming smoke that enters the second chamber through the smoke discharge port and is then expelled through the smoke outlet. Water from the first chamber flows back to the second chamber. A heater is arranged in the second chamber that can increase the temperature of the water. (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

Dry ice smoke generator

BACKGROUND OF THE INVENTION

The present invention relates to a smoke generator and, more particularly, to a smoke generator using dry ice which sublimates directly into carbon dioxide gas when heated, thereby providing a smoke effect.

Dry ice (the solid form of carbon dioxide) sublimes under heat into a gaseous state, providing a smoke effect. Dry ice smoke generators are designed based on the characteristics of dry ice and control the volume and production time of smoke generated from dry ice. A conventional dry ice smoke generator generally includes a basket with a plurality of holes. Dry ice is received in the basket. Hot water is available under the basket. When smoke generation is not desired, the basket is in a position where the dry ice in the basket is separated from the hot water. When you want to generate smoke, the basket is moved towards the hot water until the dry ice comes into contact with the hot water. Therefore, dry ice absorbs heat and sublimates into a gaseous state to produce a large amount of smoke, and the dry ice smoke generator transmits the smoke to the outside to produce a smoke effect.

However, the above conventional dry ice smoke generator cannot provide a good temperature maintenance effect, because the dry ice has to be immersed in the hot water and therefore is not isolated from the hot water. Therefore, dry ice is stored independently in a temperature maintenance box outside the dry ice smoke generator before use. During use, the dry ice is removed from the temperature maintenance box and then placed in the dry ice smoke generator, which is inconvenient to use. Additionally, the hot water temperature reduces the shelf life of dry ice during use. Due to the poor temperature maintenance effect of the dry ice smoke generator, dry ice is continuously consumed even when not in use. In case the operating time is long, the dry ice in the dry ice smoke generator may have been exhausted or insufficient to provide the desired smoke effect, and it is inappropriate to replenish the dry ice on the stage during the operating time. functioning. Additionally, due to the operation of the conventional dry ice smoke generator requiring movement of the basket to immerse the dry ice in hot water, the capacity of the dry ice smoke generator is at least twice the volume of the dry ice to allow total immersion in hot water. Therefore, most of the dry ice smoke generators currently available do not have a large capacity for dry ice, which leads to small performance and a small smoke generation time period. However, since the basket has to move along with the dry ice, the basket might be too heavy to move when loaded with a large amount of dry ice. Additionally, a bulky dry ice smoke generator is not suitable for layout on a stage and is therefore not an optimal solution.

Document CN108721917A describes a smoke generator that uses dry ice that comprises all the technical characteristics set forth in the preamble of claim 1.

BRIEF SUMMARY OF THE INVENTION

The present invention provides a smoke generator using dry ice and comprising a housing including a first chamber, a second chamber and a third chamber. The housing includes an exterior side that has a smoke outlet that interfaces with the second chamber. The first chamber includes a smoke discharge port that interfaces with the second chamber. The first chamber is configured to receive dry ice. The second chamber is configured to receive water. A separation member is arranged between the first chamber and the second chamber and located below the smoke discharge port. The separation member includes a water drain port that interfaces with the first and second chambers. The separating member is arranged inclined to locate the water drainage port at a lower location of the separating member. A water pump device is fixed in the third compartment. The water pump device includes a water inlet located in the second chamber and a water spray end located in the first chamber. The water pump device is configured to supply water in the second chamber to the first. A heater is arranged in the second chamber and configured to increase the temperature of the water. A water discharge mechanism is coupled to the separation member. The water discharge mechanism includes a valve plate normally in a first position that closes the water drain port and a support spring that pushes the valve plate to the first position. The valve plate is movable between the first closing position the water drain port and a second position revealing the water drain port. When the water level of the water in the first chamber rises to a height and imposes a loading force on the valve plate to thereby overcome the supporting spring, the valve plate moves from the first position to the second position. The water from the first chamber flows back to the second chamber.

The smoke generator according to the present invention uses the water pump device to supply the water in the second chamber to the first chamber. The water discharge mechanism allows the water in the first chamber to flow back to the second chamber. Therefore, the dry ice can continuously contact water at a higher temperature without moving the dry ice, and the dry ice can be gasified to provide a smoke effect after efficiently absorbing the heat of the water. Compared to a conventional smoke generator having the same volume (but a portion of the volume is used to allow relative displacement of the basket and dry ice), more dry ice can be received in the smoke generator according to the present invention. , prolonging the time to generate smoke. That is, the operating time of the smoke generator is prolonged.

In one example, a bottom wall is formed between the first and second chambers and is inclined. The bottom wall includes a through hole extending between the first and second chambers. The separating member is provided on the bottom wall and covers the through hole. The water drain port interfaces with the through hole when the valve plate is in the second position. The inclined bottom wall allows the water drainage port to be arranged at the lowest position of the bottom wall. This allows the water in the first chamber to be smoothly discharged from the water drain port to the second chamber.

In one example, the smoke generator further comprises an insulation cover that includes a front opening that intercommunicates with the smoke outlet and a bottom opening that intercommunicates with the front opening. The first chamber is defined by a peripheral wall located in the second chamber and a lower wall located at a lower end of the peripheral wall and extending inclinedly. The bottom wall includes a through hole extending between the first and second chambers. The separating member is provided on the bottom wall and covers the through hole. The smoke discharge port is misaligned with the smoke outlet. The insulation cap is fixed between the peripheral wall and the smoke outlet and is misaligned from the smoke discharge port. The lower opening is oriented towards the smoke discharge port and communicates with the second chamber. In one example, an overflow prevention member is arranged in the smoke discharge port and is located in the second chamber. The overflow prevention member includes a coupling portion disposed around the smoke discharge port and a deflector having one end coupled to the coupling portion. The coupling portion includes a through hole aligned with the smoke discharge port. A distal end of the deflector is located above a bottom portion of the through hole.

In one example, a smoke discharge valve is pivotally mounted on the smoke discharge port and is located in the second chamber. The smoke discharge valve normally blocks the through hole of the overflow prevention member when it is not subjected to force. When the first chamber is filled with smoke and the internal pressure in the first chamber is greater than the sum of the pressure in the second chamber and the weight of the smoke discharge valve, the smoke in the first chamber pushes the discharge valve of smoke and enters the second chamber through the through hole and smoke discharge port.

In one example, the separation member includes a thermally insulating layer separate from the water drain port.

In one example, the separation member includes a closure wall around the water drain port. The closure wall includes a plurality of holes configured to allow passage of water through the water drain port.

In one example, a basket is removably mounted in the first chamber. The basket includes a plurality of water drainage holes and at least one track portion on one face thereof. Dry ice is received in the basket. At least one positioning portion is fixed in the first camera. The positioning portion is removably coupled to the at least one track portion of the basket.

The present invention will become clearer in light of the following detailed description of illustrative embodiments of this invention described in connection with the drawings.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded perspective view of a smoke generator using dry ice of an embodiment according to the present invention.

FIG. 2 is a perspective view of the smoke generator of FIG. 1.

FIG. 3 is a cross-sectional view taken along section line 3-3 of FIG. 2.

FIG. 4 is an enlarged view of a portion of FIG. 3.

FIG. 5 is a cross-sectional view taken along section line 5-5 of FIG. 2

FIG. 6 is a cross-sectional view taken along section line 6-6 of FIG. 2.

FIG. 7 is a cross-sectional view similar to FIG. 3, illustrating a state of the smoke generator while generating smoke.

FIG. 8 is a cross-sectional view similar to FIG. 5, illustrating a state of the smoke generator while generating smoke.

FIG. 9 is a view similar to FIG. 6 with a valve plate moved to a release position.

All figures were drawn with the sole purpose of facilitating the explanation of the basic teachings of the present invention; The extensions of the figures with respect to the number, position, relationship and dimensions of the portions to form the embodiments will be explained or will be within skill in the art after the following teachings of the present invention have been read and understood. Furthermore, the exact dimensions and dimensional proportions to conform to specific strength, weight, strength and similar requirements will also be within skill in the art after the following teachings of the present invention have been read and understood.

When used in the various figures of the drawings, the same numbers designate equal or similar parts. Furthermore, when the terms "first", "second", "third", "lower", "upper", "outer", "side", "end", "portion", "height" and similar terms are used in Herein, these terms should be understood to have reference only to the structure shown in the drawings as they would appear to a person viewing the drawings and are used only to facilitate the description of the invention.

DETAILED DESCRIPTION OF THE INVENTION

With reference to FIGS. 1-6, a smoke generator 10 of an embodiment according to the present invention directly gasifies dry ice to produce smoke. The smoke generator 10 includes a housing 20 having a first chamber 24, a second chamber 26, and a third chamber 28 separated from the first chamber 24 and the second chamber 26.

The housing 20 also includes a smoke outlet 21 on an external face thereof and intercommunicating with the second chamber 26. The first chamber 24 is defined by a peripheral wall 30 located in the second chamber 26 and a lower wall 34 that extends inclinedly from a lower end of the peripheral wall 30 towards a corner. That is, the first chamber 24 is located in the second chamber 26. The peripheral wall 30 includes a smoke discharge port 32. The smoke discharger 32 and the smoke outlet 21 are on the same side, but misaligned with each other. The smoke discharger 32 is located above the smoke outlet 21 and is adjacent to an upper opening of the first chamber 24. The lower wall 34 includes a through hole 36 that extends between the first chamber 24 and the second chamber 26. One corner of the inclined bottom wall 34 is lower than the remaining corners of the bottom wall 34. The third chamber 28 is formed by recessing an outer face of the housing 20.

An overflow prevention member 46 is disposed on the peripheral wall 30 and is aligned with the smoke discharge port 32. The overflow prevention member 46 includes a coupling portion 48 disposed around the smoke discharge port 32 and a deflector 47 having one end coupled to the coupling portion 48. The coupling portion 48 includes a through hole 48A aligned with the smoke discharge port 32. A distal end 47A of the deflector 47 is located above a bottom portion of the through hole 48A.

A smoke discharge valve 50 is disposed in the smoke discharge port 32 and is pivotally mounted on the coupling portion 48 of the overflow prevention member 46. The smoke discharge valve 50 normally blocks the through hole 48A. of the overflow prevention member 46 when not subject to force.

The smoke generator 10 further includes a separation member 38 fixed in the first chamber 24 and a water discharge mechanism 52 located between the first chamber 24 and the second chamber 26. The separation member 38 includes a thermally insulating layer 38A in the shape of an intermediate layer. The separation member 38 further includes a water drain port 40 at a corner thereof and a closure wall 41 around the drain port. of water 40. The closure wall 41 includes a plurality of holes 43 that have a small size. The separation member 38 is fixed to the bottom wall 34 and covers the through hole 36. The water drainage port 40 interfaces with the through hole 36 and is located at the lowest corner of the bottom wall 34. The thermal layer Insulator 38A is used to reduce heat exchange between the first chamber 24 and the second chamber 26. The water discharge mechanism 52 is coupled to the separation member 38 and includes a support seat 54, a valve plate 56 and a support spring 58 disposed between the valve plate 56 and the support seat 54. The support seat 54 is fixed to a lower part of the separation member 38 and is located in the second chamber 26. The valve plate 56 is coupled movably to the support seat 54 and can be moved between a first position (FIG. 6) revealing the water drain port 40 and a second position (FIG. 9) closing the water drain hole 40. The spring The support plate 58 diverts the valve plate 56 to the second position by closing the water drain port 40.

A basket 42 is removably received in the first chamber 24 and includes a plurality of water drainage holes 44 and two track portions 45 on two opposite sides thereof. The first chamber 24 includes two positioning portions 24A disposed on the peripheral wall 30 and corresponding to the two track portions 45. When the basket 42 is received in the first chamber 24, the two track portions 45 are removably coupled with the two positioning portions 24A to locate the basket 42 in a central portion of the first chamber 24. The basket 42 is configured to receive at least one piece of dry ice 80.

According to the form shown, the smoke generator 10 further includes a water pump device 60 and a heating device 66. The water pump device 60 is fixed in the third chamber 28 and may comprise a water pump. The water pump device 60 further includes a water inlet 62 located in the second chamber 26 and a water spray end 64 located in the first chamber 24. When the water pump device 60 operates, the water in the second Chamber 26 is supplied to the first chamber 24. The heating device 66 is arranged in the housing 20 and includes a heater 68 located at a bottom of the second chamber 26. The heater 68 is configured to heat water in the second chamber 26. , increasing the temperature of the water.

A side cover 72 is fixed to one face of the housing 20 and is aligned with the third chamber 28. The side cover 72 covers the third chamber 28. A cover 70 is rotatably mounted on a top end of the housing 20 and is located in an opening of the first chamber 24. The cover 70 closes the first chamber 24 when it is in a closed position.

The smoke generator 10 further includes an insulation cover 74. The insulation cover 74 includes a front opening 77 aligned with the smoke outlet 21 (which is misaligned from the smoke discharge port 32) and a bottom opening 76 aligned with the second chamber 26 and facing the smoke discharge port 32. The insulation cover 74 is arranged between the smoke outlet 21 and the peripheral wall 30. One end of the front opening 77 is received in the smoke outlet 21. The Lower opening 76 of the insulation cover 74 faces the heater 68 in the second chamber 26.

For the sake of explanation, it is assumed that 8 pieces of dry ice 80 are placed in the basket 42. The water 82 in a suitable amount is received in the second chamber 26 and has a depth sufficient to submerge the heater 68 of the heating device. 66. The water 82 is at a normal temperature when the smoke generator 10 is not operating. The dry ice 80 is separated from the water 82 by the separation member 38. Therefore, the dry ice 80 can be well preserved when the smoke generator 10 is not operating.

With reference to FIGS. 7-8, when it is desired to generate smoke, the heater 68 heats the water 82 to increase the temperature. The water pump device 60 sucks the water 82 at a higher temperature through the water inlet 62 and discharges the water 82 through the water spray end 64, so that the water level in the first chamber 24 increases. When the water 82 at a higher temperature in the first chamber 24 rises and enters the basket 42 through the plurality of water drainage holes 44 to contact the dry ice 80, the dry ice 80 absorbs the heat of the water and gasifies into smoke. When smoke fills the first chamber 24 to an extent that the internal pressure in the first chamber 24 is greater than the sum of the pressure in the second chamber 26 and the weight of the smoke discharge valve 50, the smoke in The first chamber 24 opens the smoke discharge valve 50 and enters the remaining water-free space in the second chamber 26 through the through hole 48A and the smoke discharge port 32.

It is noted that due to the insulation cover 74, the smoke emerging from the first chamber 24 will not be directly discharged through the smoke outlet 21. Since the lower opening 76 of the insulation cover 74 is separated from the smoke discharge port 32, the smoke emerging from the first chamber 24 will first enter and spread throughout the second chamber 26, then passes through the bottom opening 76 and the front opening 77 of the insulation cover 74 , and finally exits through the smoke outlet 21. The advantage of this design is that the water vapor resulting from the water 82 at a higher temperature is less likely to be expelled from the first chamber 24 along with the smoke. Therefore, the smoke expelled out of the smoke outlet 21 is drier. Furthermore, the baffle 47 of the overflow prevention member 46 can prevent water, water spray or humidity induced in the first chamber 24 from overflowing through the through hole 48A or the smoke discharge port 32. Furthermore, When the water in the first chamber 24 passes through the plurality of holes 43 in the peripheral wall 41 toward an interior of the peripheral wall 41, the pressure of the water increases the pressure imparted to the valve plate 56. When the pressure ( a load force) imparted to the valve plate 56 exceeds the deflection force of the support spring 58, the valve plate 56 moves from the second position that closes the water drain hole 40 to the first position that reveals the water drain port 40. Therefore, the water filled in the first chamber 24 can flow through the water drain port 40 and the through hole 36 and then flow back to the second chamber 26, so that the Water 82 whose temperature is reduced can be heated again.

The smoke generator 10 according to the present invention uses the water pump device 60 to supply the water 82 in the second chamber 26 to the first chamber 24. The water discharge mechanism 52 allows the water in the first chamber 24 to flow back to the second chamber 26. Therefore, the dry ice 80 can be continuously contacted with the water 82 at a higher temperature without moving the dry ice 80, and the dry ice 80 can be gasified to provide a smoke effect. after efficiently absorbing heat from 82 water. Compared to a conventional smoke generator that has the same volume (but a portion of the volume is used to allow relative displacement of the basket and dry ice), more ice can be received dry 80 in the smoke generator according to the present invention, prolonging the time to generate smoke. That is, the operating time of the smoke generator 10 is prolonged.

Since the basket 42 and the dry ice 80 do not have to move, it is not necessary to consider the shifting load problem of the dry ice 80 when designing the smoke generator 10. Although the basket 42 is enlarged and therefore Therefore, the load increases, the operation of the entire smoke generator 10 is not directly affected. This further allows an increase in the volume of the smoke generator 10 to receive more dry ice 80 into the smoke generator 10, more effectively prolonging the operating time of the smoke generator 10.

By controlling the flow of the plurality of holes 43 and the water pump device 60, the water level in the first chamber 24 can be easily controlled. The water level in the first chamber 24 is lower when the flow of the water pump device 60 is lower and a smaller amount of smoke is generated. On the other hand, the water level in the first chamber 24 is higher when the flow of the water pump device 60 is larger, and a larger amount of smoke is generated.

Another advantage of the smoke generator 10 according to the present invention is the separation member 38 arranged between the first chamber 24 and the second chamber 26. The thermally insulating layer 38A of the separation member 38 can reduce heat conduction from the water 82 to the interior of the first chamber 24. This further extends the storage time of the dry ice 80 in the first chamber 24.

Since the lower opening 76 of the insulation cap 74 faces the heater 68, the water vapor resulting from the water 82 at a higher temperature is less likely to be expelled from the first chamber 24 along with the smoke. Therefore, the smoke expelled out of the smoke outlet 21 is drier.

Due to the arrangement of the overflow prevention member 46, the possibility of water in the first chamber 24 passing through the smoke discharge port 32 is effectively reduced. The insulation cap 74 further reduces the risk of water dripping through the smoke outlet 21.

The inclinedly arranged bottom wall 34 allows the water drain port 40 to be arranged at the lowest position of the bottom wall 34. This allows the water 82 in the first chamber 24 to be smoothly discharged from the water drain port 40. towards the second chamber 26.

Now that the basic teachings of the present invention have been explained, many extensions and variations will be obvious to one skilled in the art. For example, the smoke generator 10 does not have to include the basket 42, and the dry ice 80 can still be received in the first chamber 24 and can be directly gasified into smoke after coming into contact with hot water.

Therefore, since the invention described in this description can be carried out in other specific ways without Departing from the spirit or general characteristics thereof, some of the forms of which have been indicated, the embodiments described in this invention should be considered illustrative in every sense and not restrictive. The scope of the invention is defined by the attached claims.

Claims (8)

1. A smoke generator using dry ice, comprising: a housing (20) that includes a first chamber (24), a second chamber (26) and a third chamber (28), where the housing includes an exterior side that has a smoke outlet (21) that intercommunicates with the second chamber, wherein the first chamber includes a smoke discharge port that intercommunicates with the second chamber, wherein the first chamber is configured to receive dry ice (80), and where the second chamber is configured to receive water; a separation member (38) disposed between the first chamber and the second chamber and located below the smoke discharge port, where the separation member includes a water drainage port (40) that intercommunicates with the first and second chambers , wherein the separation member is arranged inclined to locate the water drain port at a lower location of the separation member; a water pump device (60) fixed in the third compartment, where the water pump device includes a water inlet (62) located in the second chamber and a water spray end located in the first chamber, where the water pump device is configured to supply water in the second chamber to the first; a heater (68) disposed in the second chamber and configured to increase the temperature of the water; and a water discharge mechanism (52) coupled to the separation member, wherein the water discharge mechanism includes a valve plate (56) typically in a first position that closes the water drain port; characterized in that the water discharge mechanism further includes a support spring (58) that pushes the valve plate to the first position, wherein the valve plate is movable between the first position that closes the water drain port and a second position revealing the water drain port, where when the water level of the water in the first chamber rises to a height and imparts a loading force to the valve plate to thereby overcome the supporting spring, the valve plate is moves from the first position to the second position, and the water in the first chamber flows back to the second chamber. 2. The smoke generator using dry ice according to claim 1, wherein a bottom wall (34) is formed between the first and second chambers and is inclined, wherein the bottom wall includes a through hole extending between the first and second chambers. second, where the separation member is provided on the bottom wall and covers the through hole, and where the water drain port interfaces with the through hole when the valve plate is in the second position. 3. The smoke generator using dry ice according to claim 1, further comprising an insulation cover that includes a front opening (77) that intercommunicates with the smoke outlet and a lower opening (76) that intercommunicates with the front opening, where the first chamber is defined by a peripheral wall located in the second chamber and a lower wall located at a lower end of the peripheral wall and extending inclinedly, where the lower wall includes a through hole that extends between the first and second chambers, where the separation member is arranged on the bottom wall and covers the through hole, where the smoke discharge port is misaligned from the smoke outlet, where the insulation cap is fixed between the peripheral wall and the smoke outlet and is misaligned with the smoke discharge port, and where the lower opening is oriented towards the smoke discharge port and intercommunicates with the second chamber. 4. The smoke generator using dry ice according to claim 1, wherein an overflow prevention member (46) is disposed in the smoke discharge port and is located in the second chamber, wherein the overflow prevention member includes a coupling portion (48) disposed around the smoke discharge port and a deflector having one end coupled to the coupling portion, wherein the coupling portion includes a through hole aligned with the smoke discharge port, and where a distal end of the deflector is located above a bottom of the through hole. 5. The smoke generator using dry ice according to claim 4, further comprising a smoke discharge valve (50) pivotally mounted in the smoke discharge port and located in the second chamber, where the discharge valve of smoke normally blocks the through hole of the overflow prevention member when not subjected to force, where when the first chamber is filled with smoke and the internal pressure in the first chamber is greater than the sum of the pressure in the second chamber and the weight of the smoke discharge valve, the smoke in the first chamber pushes the smoke discharge valve and enters the second chamber through the through hole and smoke discharge port. 6. The smoke generator using dry ice according to claim 1, wherein the separation member includes a thermally insulating layer (38a) separated from the water drain port. 7. The smoke generator using dry ice according to claim 1, wherein the separation member includes a closure wall (41) around the water drainage port, wherein the closure wall includes a plurality of holes (43) configured to allow water to pass through the water drain port. 8. The smoke generator using dry ice as claimed in claim 1, further comprising: a basket (42) removably mounted in the first chamber, wherein the basket includes multiple water drainage holes and at least one portion of track on one face thereof, where dry ice is received in the basket; and at least one positioning portion fixed in the first chamber, wherein the positioning portion is removably coupled to the at least one track portion of the basket.